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  • 3.E: Polynomial and Rational Functions(Exercises)
    https://math.libretexts.org/Courses/Coastline_College/Math_C170%3A_Precalculus_(Tran)/03%3A_Polynomial_and_Rational_Functions/3.E%3A_Polynomial_and_Rational_Functions(Exercises)
    After all, to this point we have described the square root of a negative number as undefined. Fortunately, there is another system of numbers that provides solutions to problems such as these. In this...After all, to this point we have described the square root of a negative number as undefined. Fortunately, there is another system of numbers that provides solutions to problems such as these. In this section, we will explore this number system and how to work within it.
  • 3.1: Complex Numbers Review
    https://math.libretexts.org/Courses/Highline_College/Math_141%3A_Precalculus_I_(old_edition)/03%3A_Polynomial_and_Rational_Functions/3.01%3A_Complex_Numbers_Review
    After all, to this point we have described the square root of a negative number as undefined. Fortunately, there is another system of numbers that provides solutions to problems such as these. In this...After all, to this point we have described the square root of a negative number as undefined. Fortunately, there is another system of numbers that provides solutions to problems such as these. In this section, we will explore this number system and how to work within it.
  • 2.4: Complex Numbers
    https://math.libretexts.org/Courses/Angelo_State_University/Finite_Mathematics/02%3A_Equations_and_Inequalities/2.04%3A_Complex_Numbers
    In this section, we will explore a set of numbers that fills voids in the set of real numbers and find out how to work within it.
  • 2.4: Complex Numbers
    https://math.libretexts.org/Courses/Chabot_College/Chabot_College_College_Algebra_for_BSTEM/02%3A_Equations_and_Inequalities/2.04%3A_Complex_Numbers
    The square root of any negative number can be written as a multiple of i. To plot a complex number, we use two number lines, crossed to form the complex plane. The horizontal axis is the real axis, an...The square root of any negative number can be written as a multiple of i. To plot a complex number, we use two number lines, crossed to form the complex plane. The horizontal axis is the real axis, and the vertical axis is the imaginary axis. Complex numbers can be added and subtracted by combining the real parts and combining the imaginary parts. Complex numbers can be multiplied and divided.
  • 3.2: Complex Numbers
    https://math.libretexts.org/Bookshelves/Precalculus/Precalculus_2e_(OpenStax)/03%3A_Polynomial_and_Rational_Functions/3.02%3A_Complex_Numbers
    After all, to this point we have described the square root of a negative number as undefined. Fortunately, there is another system of numbers that provides solutions to problems such as these. In this...After all, to this point we have described the square root of a negative number as undefined. Fortunately, there is another system of numbers that provides solutions to problems such as these. In this section, we will explore this number system and how to work within it.
  • 2.5: Complex Numbers
    https://math.libretexts.org/Bookshelves/Algebra/College_Algebra_1e_(OpenStax)/02%3A_Equations_and_Inequalities/2.05%3A_Complex_Numbers
    The square root of any negative number can be written as a multiple of i. To plot a complex number, we use two number lines, crossed to form the complex plane. The horizontal axis is the real axis, an...The square root of any negative number can be written as a multiple of i. To plot a complex number, we use two number lines, crossed to form the complex plane. The horizontal axis is the real axis, and the vertical axis is the imaginary axis. Complex numbers can be added and subtracted by combining the real parts and combining the imaginary parts. Complex numbers can be multiplied and divided.
  • 21.1: Polar Form of Complex Numbers
    https://math.libretexts.org/Bookshelves/Precalculus/Precalculus_(Tradler_and_Carley)/21%3A_Complex_Numbers/21.01%3A_Polar_Form_of_Complex_Numbers
    We now recall the definition of complex numbers and show how they are represented on the complex plane.
  • 11.7: Polar Form of Complex Numbers
    https://math.libretexts.org/Courses/Lorain_County_Community_College/Book%3A_Precalculus_(Stitz-Zeager)_-_Jen_Test_Copy/11%3A_Applications_of_Trigonometry/11.07%3A_Polar_Form_of_Complex_Numbers
    In this section, we return to our study of complex numbers. We associate each complex number z=a+biz=a+bi with the point (a,b)(a,b) on the coordinate plane. In this case, the xx -axis is relabele...In this section, we return to our study of complex numbers. We associate each complex number z=a+biz=a+bi with the point (a,b)(a,b) on the coordinate plane. In this case, the xx -axis is relabeled as the real axis, which corresponds to the real number line as usual, and the yy -axis is relabeled as the imaginary axis, which is demarcated in increments of the imaginary unit ii . The plane determined by these two axes is called the complex plane.
  • 4.E: Polynomial and Rational Functions (Exercises)
    https://math.libretexts.org/Courses/Highline_College/MATHP_141%3A_Corequisite_Precalculus/04%3A_Polynomial_and_Rational_Functions/4.E%3A_Polynomial_and_Rational_Functions_(Exercises)
    For the exercises 75-78, use the vertex of the graph of the quadratic function and the direction the graph opens to find the domain and range of the function. The \(x\)-intercept is where the graph of...For the exercises 75-78, use the vertex of the graph of the quadratic function and the direction the graph opens to find the domain and range of the function. The \(x\)-intercept is where the graph of the function crosses the \(x\)-axis, and the zero of the function is the input value for which \(f(x)=0\).
  • 1.4.E: Polynomial and Rational Functions (Exercises)
    https://math.libretexts.org/Courses/Coastline_College/Math_C097%3A_Support_for_Precalculus_Corequisite%3A_MATH_C170/1.04%3A_Polynomial_and_Rational_Functions/1.4.E%3A_Polynomial_and_Rational_Functions_(Exercises)
    For the exercises 75-78, use the vertex of the graph of the quadratic function and the direction the graph opens to find the domain and range of the function. The \(x\)-intercept is where the graph of...For the exercises 75-78, use the vertex of the graph of the quadratic function and the direction the graph opens to find the domain and range of the function. The \(x\)-intercept is where the graph of the function crosses the \(x\)-axis, and the zero of the function is the input value for which \(f(x)=0\).
  • 1.8: Complex Numbers
    https://math.libretexts.org/Courses/Palo_Alto_College/College_Algebra/01%3A_Prerequisites/1.08%3A_Complex_Numbers
    The square root of any negative number can be written as a multiple of i. To plot a complex number, we use two number lines, crossed to form the complex plane. The horizontal axis is the real axis, an...The square root of any negative number can be written as a multiple of i. To plot a complex number, we use two number lines, crossed to form the complex plane. The horizontal axis is the real axis, and the vertical axis is the imaginary axis. Complex numbers can be added and subtracted by combining the real parts and combining the imaginary parts. Complex numbers can be multiplied and divided.

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