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Complex solutions to quadratic equations. Complex solutions to quadratic equations. 1 / 10 Complex numbers Motivation: Is there a solution to 2x = 1 if you are only allowed to look in the integers? Complex solutions to quadratic equations. 2 / 10 Complex numbers Motivation: Is there a solution to 2x = 1 if you are only allowed to look in the integers? Nope, you have to consider rational numbers to solve this kind of equation. Complex solutions to quadratic equations. 2 / 10 Complex numbers Motivation: Is there a solution to 2x = 1 if you are only allowed to look in the integers? Nope, you have to consider rational numbers to solve this kind of equation. Is there a solution to x 2 = 2 if you are only allowed to look in the rational numbers? Complex solutions to quadratic equations. 2 / 10 Complex numbers Motivation: Is there a solution to 2x = 1 if you are only allowed to look in the integers? Nope, you have to consider rational numbers to solve this kind of equation. Is there a solution to x 2 = 2 if you are only allowed to look in the rational numbers? Nope, you have to consider real numbers to solve this kind of equation. Complex solutions to quadratic equations. 2 / 10 Complex numbers Motivation: Is there a solution to 2x = 1 if you are only allowed to look in the integers? Nope, you have to consider rational numbers to solve this kind of equation. Is there a solution to x 2 = 2 if you are only allowed to look in the rational numbers? Nope, you have to consider real numbers to solve this kind of equation. Is there a solution to x 2 = −1 if you are only allowed to look in the real numbers? Complex solutions to quadratic equations. 2 / 10 Complex numbers Motivation: Is there a solution to 2x = 1 if you are only allowed to look in the integers? Nope, you have to consider rational numbers to solve this kind of equation. Is there a solution to x 2 = 2 if you are only allowed to look in the rational numbers? Nope, you have to consider real numbers to solve this kind of equation. Is there a solution to x 2 = −1 if you are only allowed to look in the real numbers? Nope, you have to consider complex numbers to solve this kind of equation. Complex solutions to quadratic equations. 2 / 10 Complex numbers Motivation: Is there a solution to 2x = 1 if you are only allowed to look in the integers? Nope, you have to consider rational numbers to solve this kind of equation. Is there a solution to x 2 = 2 if you are only allowed to look in the rational numbers? Nope, you have to consider real numbers to solve this kind of equation. Is there a solution to x 2 = −1 if you are only allowed to look in the real numbers? Nope, you have to consider complex numbers to solve this kind of equation. We will add to the reals a symbol which represents a square root of −1. Complex solutions to quadratic equations. 2 / 10 Complex numbers The imaginary unit i is a formal symbol which we define to have the property that i2 = −1. Complex solutions to quadratic equations. 3 / 10 Complex numbers The imaginary unit i is a formal symbol which we define to have the property that i2 = −1. A complex number is a quantity of the form a + bi where a and b are real numbers. Complex solutions to quadratic equations. 3 / 10 Complex numbers The imaginary unit i is a formal symbol which we define to have the property that i2 = −1. A complex number is a quantity of the form a + bi where a and b are real numbers. If b = 0 then a + bi is called a real number, if a = 0 then a + bi is called imaginary. Complex solutions to quadratic equations. 3 / 10 Complex numbers The imaginary unit i is a formal symbol which we define to have the property that i2 = −1. A complex number is a quantity of the form a + bi where a and b are real numbers. If b = 0 then a + bi is called a real number, if a = 0 then a + bi is called imaginary. Can we do arithmetic with complex numbers? Complex solutions to quadratic equations. 3 / 10 Complex numbers The imaginary unit i is a formal symbol which we define to have the property that i2 = −1. A complex number is a quantity of the form a + bi where a and b are real numbers. If b = 0 then a + bi is called a real number, if a = 0 then a + bi is called imaginary. Can we do arithmetic with complex numbers? Addition and subtraction: What should (a + bi) + (c + di) mean? a + bi + c + di = Complex solutions to quadratic equations. 3 / 10 Complex numbers The imaginary unit i is a formal symbol which we define to have the property that i2 = −1. A complex number is a quantity of the form a + bi where a and b are real numbers. If b = 0 then a + bi is called a real number, if a = 0 then a + bi is called imaginary. Can we do arithmetic with complex numbers? Addition and subtraction: What should (a + bi) + (c + di) mean? a + bi + c + di = (a + c) + (b + d)i In order to add / subtract complex numbers just add / subtract the real and imaginary parts. Complex solutions to quadratic equations. 3 / 10 Complex numbers The imaginary unit i is a formal symbol which we define to have the property that i2 = −1. A complex number is a quantity of the form a + bi where a and b are real numbers. If b = 0 then a + bi is called a real number, if a = 0 then a + bi is called imaginary. Can we do arithmetic with complex numbers? Addition and subtraction: What should (a + bi) + (c + di) mean? a + bi + c + di = (a + c) + (b + d)i In order to add / subtract complex numbers just add / subtract the real and imaginary parts. Compute (2 + 3i) − (3 + 2i). Complex solutions to quadratic equations. 3 / 10 multiplication The FOIL’ing rule lets us multiply complex numbers: (a + bi) · (c + di) = Complex solutions to quadratic equations. 4 / 10 multiplication The FOIL’ing rule lets us multiply complex numbers: (a + bi) · (c + di) = ac + adi + bci + bdi2 = Complex solutions to quadratic equations. 4 / 10 multiplication The FOIL’ing rule lets us multiply complex numbers: (a + bi) · (c + di) = ac + adi + bci + bdi2 = (ac − bd) + (ad + bc)i Complex solutions to quadratic equations. 4 / 10 multiplication The FOIL’ing rule lets us multiply complex numbers: (a + bi) · (c + di) = ac + adi + bci + bdi2 = (ac − bd) + (ad + bc)i Compute: (2 + 3i) · (2 − 3i) (1 + i)4 Complex solutions to quadratic equations. 4 / 10 Complex conjugation For a complex number z = a + bi, its conjugate is given by z = a + bi = Complex solutions to quadratic equations. 5 / 10 Complex conjugation For a complex number z = a + bi, its conjugate is given by z = a + bi = a − bi To compute the conjugate just negate the imaginary part. Notice that z · z = (a + bi) · (a + bi) = Complex solutions to quadratic equations. 5 / 10 Complex conjugation For a complex number z = a + bi, its conjugate is given by z = a + bi = a − bi To compute the conjugate just negate the imaginary part. Notice that z · z = (a + bi) · (a + bi) = (a + bi)(a − bi) = Complex solutions to quadratic equations. 5 / 10 Complex conjugation For a complex number z = a + bi, its conjugate is given by z = a + bi = a − bi To compute the conjugate just negate the imaginary part. Notice that z · z = (a + bi) · (a + bi) = (a + bi)(a − bi) = ... = Complex solutions to quadratic equations. 5 / 10 Complex conjugation For a complex number z = a + bi, its conjugate is given by z = a + bi = a − bi To compute the conjugate just negate the imaginary part. Notice that z · z = (a + bi) · (a + bi) = (a + bi)(a − bi) = ... = a2 + b 2 + 0i Complex solutions to quadratic equations. 5 / 10 Complex conjugation For a complex number z = a + bi, its conjugate is given by z = a + bi = a − bi To compute the conjugate just negate the imaginary part. Notice that z · z = (a + bi) · (a + bi) = (a + bi)(a − bi) = ... = a2 + b 2 + 0i Multiplying a complex number by its conjugate always produces a positive real number. Compute (2 + 3i) · (2 + 3i). Complex solutions to quadratic equations. 5 / 10 Dividing a complex number by a real number To divide a complex number by a real number just divide the real and imaginary components: a + bi = c Complex solutions to quadratic equations. 6 / 10 Dividing a complex number by a real number To divide a complex number by a real number just divide the real and imaginary components: a + bi a b = + i c c c It is harder to divide by a complex number. a + bi How can we make sense of ? c + di Multiply and divide by the conjugate! a + bi = c + di Complex solutions to quadratic equations. 6 / 10 Dividing a complex number by a real number To divide a complex number by a real number just divide the real and imaginary components: a + bi a b = + i c c c It is harder to divide by a complex number. a + bi How can we make sense of ? c + di Multiply and divide by the conjugate! a + bi (a + bi)(c − di) = = c + di (c + di)(c − di) Complex solutions to quadratic equations. 6 / 10 Dividing a complex number by a real number To divide a complex number by a real number just divide the real and imaginary components: a + bi a b = + i c c c It is harder to divide by a complex number. a + bi How can we make sense of ? c + di Multiply and divide by the conjugate! a + bi (a + bi)(c − di) ac + bd + (bc − ad)i = = = c + di (c + di)(c − di) c2 + d2 Complex solutions to quadratic equations. 6 / 10 Dividing a complex number by a real number To divide a complex number by a real number just divide the real and imaginary components: a + bi a b = + i c c c It is harder to divide by a complex number. a + bi How can we make sense of ? c + di Multiply and divide by the conjugate! a + bi (a + bi)(c − di) ac + bd + (bc − ad)i = = = c + di (c + di)(c − di) c2 + d2 ac + bd bc − ad + 2 i 2 2 c +d c + d2 1+i 2+i Compute and 2+i 1 + 2i Complex solutions to quadratic equations. 6 / 10 Square roots of negative numbers We’ve formally added a solution to x 2 = −1. Have we added more than that? √ Compute (i 7)2 = Complex solutions to quadratic equations. 7 / 10 Square roots of negative numbers We’ve formally added a solution to x 2 = −1. Have we added more than that? √ √ Compute (i 7)2 = i2 · ( 7)2 = Complex solutions to quadratic equations. 7 / 10 Square roots of negative numbers We’ve formally added a solution to x 2 = −1. Have we added more than that? √ √ Compute (i 7)2 = i2 · ( 7)2 = − 7 √ √ We have also added a square root to −7: −7 = i 7 The √ same√is true for all negative numbers, −n = i n. Complex solutions to quadratic equations. 7 / 10 Solutions to quadratics Solve x 2 + 3x + 5 = 0: By the quadratic formula the solution is x= Complex solutions to quadratic equations. 8 / 10 Solutions to quadratics Solve x 2 + 3x + 5 = 0: By the quadratic formula the solution is √ −3 ± 32 − 4 · 5 x= = 2 Complex solutions to quadratic equations. 8 / 10 Solutions to quadratics Solve x 2 + 3x + 5 = 0: By the quadratic formula the solution is √ √ −3 ± 32 − 4 · 5 −3 ± −11 x= = = 2 2 Complex solutions to quadratic equations. 8 / 10 Solutions to quadratics Solve x 2 + 3x + 5 = 0: By the quadratic formula the solution is √ √ √ −3 ± 32 − 4 · 5 −3 ± −11 −3 ± i 11 x= = = 2 2 2 Complex solutions to quadratic equations. 8 / 10 Solutions to quadratics Solve x 2 + 3x + 5 = 0: By the quadratic formula the solution is √ √ √ −3 ± 32 − 4 · 5 −3 ± −11 −3 ± i 11 x= = = 2 2 2 Quadratic equations always have solutions, provided you allow complex numbers to appear. For you: Solve x 2 − 2x + 2 = 0. Complex solutions to quadratic equations. 8 / 10 How are complex roots related to each other? So far we have seen that: The solutions to x 2 + 3x√+ 5 = 0 are √ 11 −3 11 −3 + i and − i 2 2 2 2 The solutions to x 2 − 2x + 2 = 0 are 1 + i and 1 − i They are related by complex conjugation. Theorem If the quadratic equation ax 2 + bx + c = 0 has a complex solution a + bi then its other solution is the complex conjugate: a − bi Complex solutions to quadratic equations. 9 / 10 Some practice Solve 1 x2 + 4 = 0 2 x2 − 4 = 0 3 x 2 + 4x + 9 = 0 4 x 2 − 4x − 9 = 0 5 x 2 + 4x + 4 = 0 6 x 2 − 4x − 4 = 0 Complex solutions to quadratic equations. 10 / 10
