Questions tagged [polynomials]

For both basic and advanced questions on polynomials in any number of variables, including, but not limited to solving for roots, factoring, and checking for irreducibility.

Usually, polynomials are introduced as expressions of the form $\sum_{i=0}^dc_ix^i$ such as $15x^3 - 14x^2 + 8$. Here, the numbers are called coefficients, the $x$'s are the variables or indeterminates of the polynomial, and $d$ is known as the degree of the polynomial. In general the coefficients may be taken from any ring $R$ and any finite number of variables is allowed. The set of all polynomials in $n$ variables $X_1,\ldots,X_n$ over a ring $R$ is denoted by $R[X_1,\ldots,X_n]$. Strictly speaking this is a formal sum, because the variables do not represent any value. Nevertheless, the variables of a polynomial obey the usual arithmetic laws in a ring (like commutativity and distributivity). This makes $R[X_1,\ldots,X_n]$ a ring itself. One should note that $R[X_1][X_2]=R[X_1,X_2]$. This idea can be extended to $R[X_1,\ldots,X_n]$ in a very natural way.

An expression of the form $rX_1^{i_1}X_2^{i_2}\cdots X_n^{i_n}$ ($r\in R$) is called a term (of the polynomial). Polynomials are defined to have only finitely many terms. An expression with infinitely many different terms is generally not considered to be a polynomial, but a (formal) power series in one or more variables.

When $P\in R[X]$, $P(x)$ is the evaluation of $P$ at $x$ (pronounced $P$ of $x$, or simply $Px$). Here $x$ does not necessarily have to be an element of $R$. For $P(x)$ to be properly defined for an $x$ in some ring $S$ we need:

  • a homomorphism $\phi:R\to S$
  • the image of all coefficients of $P$ under $\phi$ should commute with $x$.

Evaluation is now simply performed by replacing all coefficients $r_i$ of $P$ by $\phi(r_i)$ and all appearances of $X$ by $x$. This quite naturally gives an expression that is well defined as an element of $S$. The concept of evaluation is naturally extended to $R[X_1,\ldots,X_n]$.

26755 questions
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Finding roots $x_1$, $x_2$, $x_3$ of $x^3+ax+a=0$ (for real $a\neq 0$) if $\sum_{cyc}\frac{x_1^2}{x_2}=-8$

This question is taken from AMTI 1994: The solutions $x_1$, $x_2$, $x_3$ of the equation $x^3+ax+a=0$, where $a\ne0$ is real, satisfy $$\frac{x_1^2}{x_2}+\frac{x_2^2}{x_3}+\frac{x_3^2}{x_1}=-8$$ Find $x_1$, $x_2$, $x_3$. I tried to solve this by…
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How to utilize the remainder theorem when the quotient is unknown?

I encountered this question, and I am unsure how to answer it. When $P(x)$ is divided by $x - 4$, the remainder is $13$, and when $P(x)$ is divided by $x + 3$, the remainder is $-1$. Find the remainder when $P(x)$ is divided by $x^2 - x - 12$. How…
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How to find g(x) and its remainder

The question is as shown below. When a polynomial $g(x)$ is divided by $x^2 - 4$, the remainder is $\alpha x + \beta$, where $\alpha$ and $\beta$ are constant. Determine the values of $\alpha$ and $\beta$ given that $x + 2$ is a factor of $g(x)$,…
lim
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a recursion in roots of the polynomial

let $P(x)$ is a polynomial which satisfies property $\psi$ where property $\psi$ is given by whenever r is a root of $P(x) = 0$ then $r^2 - 4$ is also a root of the given equation. i) if $P(x)$ is a quadratic polynomial of the form $x^2 + ax + b$…
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Give a generating set for $Syz(h_1,h_2,h_3,h_4)$

I have a question which asks for a generating set of Syz($h_1,h_2,h_3,h_4$) where $h_1=x^2y+z^2$ $h_2=zy^2+yx^3$ $h_3=xz-y^2$ $h_4=y^4+yx^4$ I know that it is formed by... $Syz(h_1,h_2,...h_m)=$ {$\alpha \in R^m |…
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Prove that if $x^{nm}- a$ is irreducible then $x^n-a$ and $x^m-a$ is irreducible

Let $a \neq 0$ and let $x^{nm}- a$ be a polynomial. Prove that if $x^{nm}- a$ is irreducible then $x^n-a$ and $x^m-a$ are irreducible. $\textbf{My attempt:}$ Suppose that $x^{m}-a$ is reducible, then there exists $p,q$ s.t $x^m-a = p(x)q(x)$, with…
Joãonani
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Number of distinct real roots

The equation $x^6 − 5x^4 + 16x^2 − 72x+ 9 = 0$ has (A) exactly two distinct real roots (B) exactly three distinct real roots (C) exactly four distinct real roots (D) six distinct real roots. $f(0)>0$ and $f(1)<0$ and $f(3)>0$, so there should be an…
kris91
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Roots and Coefficients

The polynomial $P(x)$ has integer coefficients $p+\sqrt{q}$ is a root of the polynomial, where $p, q$ are rational Prove that $p-\sqrt{q}$ must also be a root of the polynomial. (Assume that q is not the square of a rational number).
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Polynomials maps on $\phi \mathbb{A}^1_k \rightarrow \mathbb{A}^2_k$

I have the following question which seems to come up every year in exam papers, but just different numbers...Im really stuck on some parts... Define $\phi: \mathbb{A}^1_k\rightarrow \mathbb{A}^2_k$ by $\phi(t)=(t^2-1,t^3+2)$ (i) Describe the induced…
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Factoring a polynomial over real numbers (no real roots)

Polynomial is: $$4x^4+2x+\frac{15}{16}$$ I know that the degree of the highest irreducible polynomial over reals is 2, so it should be possible to factor this polynomial into two second degree polynomials?
user1242967
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Unifromly discrete bound

Given $1<\beta_1<\beta_2<2$, and $k\in\mathbb{N^+}, $ $k\geq2 $ define $$ D_k=\{\sum_{j=0}^{k-1}A^jd_{i_j}:d_{i_j}\in\{(0,0)\,,(1,1)\}\} $$ where$ A=\left(\begin{array}{cc}\beta_1&0\\0&\beta_2\end{array}\right)$ then there exists $\delta>0$ such…
Tao
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Finding the intersection of $c(ax + b)^k$ curves

I am trying to find a positive solution for equations of the following form $$c_1 (a_1 x + b_1) ^ {k_1} = c_2 (a_2 x + b_2) ^ {k_2}$$ where constants $a_1$, $a_2$, $c_1$, $c_2$ are non-zero and $k_1$, $k_2$ greater than $1$ (not necessarily…
raugfer
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equivalence of polynomial expressions

I like to define a "polynomial expression" in the ring $A$ as any expression involving addition and multiplication of elements of $A$ together with one indeterminate $x$. Such expression can be manipulated by substituting any operation involving…
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Conversion ${\left( {x - a} \right)^4} + {\left( {x - b} \right)^4} = A$ into polynomial of degree 2

Convert the following polynomial of degree 4 ${\left( {x - a} \right)^4} + {\left( {x - b} \right)^4} = A$ into polynomial of degree 2 My approach is as follow $y = \frac{{{{\left( {x - a} \right)}^2} + {{\left( {x - b} \right)}^2}}}{2}$ $4{y^2} =…
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If $a,b,c \in \mathbb R$ and $a \neq 0$ then for the system of quadratic equations in n variables $x_1, x_2 ... x_n$

If $a,b,c \in \mathbb R$ and $a \neq 0$ then for the system of quadratic equations in n variables $x_1, x_2 ... x_n$ $ax_1^2+bx_1+c=x_2$ $ax_2^2+bx_2+c=x_3$ . . . $ax_n^2+bx_n+c=x_1$ $1)$ show that that the equations have no solutions if…
Tony
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