{"id":1963,"date":"2024-06-25T02:28:53","date_gmt":"2024-06-25T02:28:53","guid":{"rendered":"https:\/\/content.one.lumenlearning.com\/collegealgebra\/?post_type=chapter&p=1963"},"modified":"2025-10-21T02:13:24","modified_gmt":"2025-10-21T02:13:24","slug":"mastering-polynomial-functions-theorems-zeros-and-applications-learn-it-4","status":"publish","type":"chapter","link":"https:\/\/content.one.lumenlearning.com\/collegealgebra\/chapter\/mastering-polynomial-functions-theorems-zeros-and-applications-learn-it-4\/","title":{"raw":"Zeros of Polynomial Functions: Learn It 4","rendered":"Zeros of Polynomial Functions: Learn It 4"},"content":{"raw":"

The Fundamental Theorem of Algebra<\/h2>\r\nNow that we can find rational zeros for a polynomial function, we will look at a theorem that discusses the number of complex zeros of a polynomial function. The Fundamental Theorem of Algebra tells us that every polynomial function has at least one complex zero. This theorem forms the foundation for solving polynomial equations.\r\n\r\nSuppose [latex]f[\/latex] is a polynomial function of degree four and [latex]f\\left(x\\right)=0[\/latex]. The Fundamental Theorem of Algebra states that there is at least one complex solution, call it [latex]{c}_{1}[\/latex]. By the Factor Theorem, we can write [latex]f\\left(x\\right)[\/latex] as a product of [latex]x-{c}_{\\text{1}}[\/latex] and a polynomial quotient. Since [latex]x-{c}_{\\text{1}}[\/latex] is linear, the polynomial quotient will be of degree three. Now we apply the Fundamental Theorem of Algebra to the third-degree polynomial quotient. It will have at least one complex zero, call it [latex]{c}_{\\text{2}}[\/latex]. We can write the polynomial quotient as a product of [latex]x-{c}_{\\text{2}}[\/latex] and a new polynomial quotient of degree two. Continue to apply the Fundamental Theorem of Algebra until all of the zeros are found. There will be four of them and each one will yield a factor of [latex]f\\left(x\\right)[\/latex].\r\n\r\n
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Fundamental Theorem of Algebra<\/h3>\r\nThe Fundamental Theorem of Algebra states that every non-constant polynomial function has at least one complex zero.\r\n\r\nThat is, if you have a polynomial function of degree [latex]n > 0[\/latex], then [latex]f(x)[\/latex] has at least one complex zero.\r\n\r\n \r\n\r\nWe can use this theorem to argue that, if [latex]f\\left(x\\right)[\/latex] is a polynomial of degree [latex]n>0[\/latex], and a<\/em>\u00a0is a non-zero real number, then [latex]f\\left(x\\right)[\/latex] has exactly n<\/em>\u00a0linear factors.\r\n\r\n \r\n\r\nThe polynomial can be written as\r\n

[latex]f\\left(x\\right)=a\\left(x-{c}_{1}\\right)\\left(x-{c}_{2}\\right)...\\left(x-{c}_{n}\\right)[\/latex]<\/p>\r\nwhere [latex]{c}_{1},{c}_{2},...,{c}_{n}[\/latex] are complex numbers.\r\n\r\n \r\n\r\nTherefore, [latex]f\\left(x\\right)[\/latex] has n<\/em>\u00a0roots if we allow for multiplicities.\r\n\r\n<\/section>

Recall that we defined complex numbers as numbers of the form [latex]a + bi[\/latex]. To graph such numbers required the complex plane, made up of a real axis and an\u00a0imaginary<\/em> axis. This plane defined the real numbers as a subset of the complex numbers, just as the rational and irrational numbers are subsets of the real numbers.\r\n[latex]\\\\[\/latex]\r\nIn other words, each real number is also a complex number of the form [latex]a+bi[\/latex], where [latex]b=0[\/latex].<\/section>
Does every polynomial have at least one imaginary zero?<\/strong>\r\n\r\n
\r\n\r\nNo. A complex number is not necessarily imaginary. Real numbers are also complex numbers.\r\n\r\n<\/section>
Find the zeros of [latex]f\\left(x\\right)=3{x}^{3}+9{x}^{2}+x+3[\/latex] and write the function in factored form (as a product of linear factors).[reveal-answer q=\"791291\"]Show Solution[\/reveal-answer]\r\n[hidden-answer a=\"791291\"]The Rational Zero Theorem tells us that if [latex]\\frac{p}{q}[\/latex] is a zero of [latex]f\\left(x\\right)[\/latex], then [latex]p[\/latex]\u00a0is a factor of [latex]3[\/latex] and\u00a0[latex]q[\/latex]\u00a0is a factor of [latex]3[\/latex].\r\n

[latex]\\begin{array}{l}\\frac{p}{q}=\\frac{\\text{Factors of the constant term}}{\\text{Factor of the leading coefficient}}\\hfill \\\\ \\text{}\\frac{p}{q}=\\frac{\\text{Factors of 3}}{\\text{Factors of 3}}\\hfill \\end{array}[\/latex]<\/p>\r\nThe factors of [latex]3[\/latex] are [latex]\\pm 1[\/latex] and [latex]\\pm 3[\/latex]. The possible values for [latex]\\frac{p}{q}[\/latex], and therefore the possible rational zeros for the function, are [latex]\\pm 3, \\pm 1, \\text{and} \\pm \\frac{1}{3}[\/latex]. We will use synthetic division to evaluate each possible zero until we find one that gives a remainder of [latex]0[\/latex]. Let\u2019s begin with [latex]\u20133[\/latex].\r\n\r\n[caption id=\"attachment_13116\" align=\"aligncenter\" width=\"175\"]\"Synthetic<\/a> Synthetic division[\/caption]\r\n\r\nDividing by [latex]\\left(x+3\\right)[\/latex] gives a remainder of [latex]0[\/latex], so [latex]\u20133[\/latex] is a zero of the function. The polynomial can be written as [latex]\\left(x+3\\right)\\left(3{x}^{2}+1\\right)[\/latex].\r\n\r\nWe can then set the quadratic equal to [latex]0[\/latex] and solve to find the other zeros of the function.\r\n

[latex]\\begin{array}{l}3{x}^{2}+1=0\\hfill \\\\ \\text{ }{x}^{2}=-\\frac{1}{3}\\hfill \\\\ \\text{ }x=\\pm \\sqrt{-\\frac{1}{3}}=\\pm \\frac{i\\sqrt{3}}{3}\\hfill \\end{array}[\/latex]<\/p>\r\nThe zeros of [latex]f\\left(x\\right)[\/latex]\u00a0are [latex]\u20133[\/latex] and [latex]\\pm \\frac{i\\sqrt{3}}{3}[\/latex].<\/strong>\r\n\r\nThus, we can write our function in factored form:<\/strong>\r\n

[latex]f(x) = (x+3)(x-\\frac{i\\sqrt{3}}{3})(x+\\frac{i\\sqrt{3}}{3})[\/latex]<\/p>\r\nAnalysis of the Solution<\/strong>\r\n\r\nLook at the graph of the function [latex]f[\/latex]. Notice that, at [latex]x=-3[\/latex], the graph crosses the x<\/em>-axis, indicating an odd multiplicity ([latex]1[\/latex]) for the zero [latex]x=-3[\/latex]. Also note the presence of the two turning points. This means that, since there is a 3rd<\/sup> degree polynomial, we are looking at the maximum number of turning points. So, the end behavior of increasing without bound to the right and decreasing without bound to the left will continue. Thus, all the [latex]x[\/latex]-intercepts for the function are shown. So either the multiplicity of [latex]x=-3[\/latex] is [latex]1[\/latex] and there are two complex solutions, which is what we found, or the multiplicity at [latex]x=-3[\/latex] is three. Either way, our result is correct.\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"487\"]\"Graph Graph of a polynomial with labeled cross[\/caption]\r\n\r\n[\/hidden-answer]\r\n\r\n<\/section>

Find the zeros of [latex]f(x)=2{x}^{3}+5{x}^{2}-11x+4[\/latex] and write it in factored form.[reveal-answer q=\"696690\"]Show Solution[\/reveal-answer]\r\n[hidden-answer a=\"696690\"]The Rational Zero Theorem states that any rational zero, [latex]\\frac{p}{q}[\/latex], must have [latex]p[\/latex] as a factor of the constant term [latex]4[\/latex] and [latex]q[\/latex] as a factor of the leading coefficient [latex]2[\/latex].\r\n