(directly go to documentation on : Expand, Degree, Coef, Content, PrimitivePart, LeadingCoef, Monic, SquareFree, Horner, ExpandBrackets, EvaluateHornerScheme. )

19. Operations on polynomials

This chapter contains commands to manipulate polynomials. This includes functions for constructing and evaluating orthogonal polynomials.

Expand transform a polynomial to an expanded form
Degree degree of a polynomial
Coef coefficient of a polynomial
Content content of a univariate polynomial
PrimitivePart primitive part of a univariate polynomial
LeadingCoef leading coefficient of a polynomial
Monic monic part of a polynomial
SquareFree return the square-free part of polynomial
Horner convert a polynomial into the Horner form
ExpandBrackets expand all brackets
EvaluateHornerScheme fast evaluation of polynomials


Expand -- transform a polynomial to an expanded form

Standard library
Calling format:
Expand(expr)
Expand(expr, var)
Expand(expr, varlist)

Parameters:
expr -- a polynomial expression

var -- a variable

varlist -- a list of variables

Description:
This command brings a polynomial in expanded form, in which polynomials are represented in the form c0+c1*x+c2*x^2+...+c[n]*x^n. In this form, it is easier to test whether a polynomial is zero, namely by testing whether all coefficients are zero.

If the polynomial "expr" contains only one variable, the first calling sequence can be used. Otherwise, the second form should be used which explicitly mentions that "expr" should be considered as a polynomial in the variable "var". The third calling form can be used for multivariate polynomials. Firstly, the polynomial "expr" is expanded with respect to the first variable in "varlist". Then the coefficients are all expanded with respect to the second variable, and so on.

Examples:
In> PrettyPrinter'Set("PrettyForm");

True

In> Expand((1+x)^5);

 5        4         3         2
x  + 5 * x  + 10 * x  + 10 * x  + 5 * x + 1

In> Expand((1+x-y)^2, x);

 2                                2
x  + 2 * ( 1 - y ) * x + ( 1 - y )

In> Expand((1+x-y)^2, {x,y});

 2                         2
x  + ( -2 * y + 2 ) * x + y  - 2 * y + 1

See also:
ExpandBrackets .


Degree -- degree of a polynomial

Standard library
Calling format:
Degree(expr)
Degree(expr, var)

Parameters:
expr -- a polynomial

var -- a variable occurring in "expr"

Description:
This command returns the degree of the polynomial "expr" with respect to the variable "var". The degree is the highest power of "var" occurring in the polynomial. If only one variable occurs in "expr", the first calling sequence can be used. Otherwise the user should use the second form in which the variable is explicitly mentioned.

Examples:
In> Degree(x^5+x-1);
Out> 5;
In> Degree(a+b*x^3, a);
Out> 1;
In> Degree(a+b*x^3, x);
Out> 3;

See also:
Expand , Coef .


Coef -- coefficient of a polynomial

Standard library
Calling format:
Coef(expr, var, order)

Parameters:
expr -- a polynomial

var -- a variable occurring in "expr"

order -- integer or list of integers

Description:
This command returns the coefficient of "var" to the power "order" in the polynomial "expr". The parameter "order" can also be a list of integers, in which case this function returns a list of coefficients.

Examples:
In> e := Expand((a+x)^4,x)
Out> x^4+4*a*x^3+(a^2+(2*a)^2+a^2)*x^2+
(a^2*2*a+2*a^3)*x+a^4;
In> Coef(e,a,2)
Out> 6*x^2;
In> Coef(e,a,0 .. 4)
Out> {x^4,4*x^3,6*x^2,4*x,1};

See also:
Expand , Degree , LeadingCoef .


Content -- content of a univariate polynomial

Standard library
Calling format:
Content(expr)

Parameters:
expr -- univariate polynomial

Description:
This command determines the content of a univariate polynomial. The content is the greatest common divisor of all the terms in the polynomial. Every polynomial can be written as the product of the content with the primitive part.

Examples:
In> poly := 2*x^2 + 4*x;
Out> 2*x^2+4*x;
In> c := Content(poly);
Out> 2*x;
In> pp := PrimitivePart(poly);
Out> x+2;
In> Expand(pp*c);
Out> 2*x^2+4*x;

See also:
PrimitivePart , Gcd .


PrimitivePart -- primitive part of a univariate polynomial

Standard library
Calling format:
PrimitivePart(expr)

Parameters:
expr -- univariate polynomial

Description:
This command determines the primitive part of a univariate polynomial. The primitive part is what remains after the content (the greatest common divisor of all the terms) is divided out. So the product of the content and the primitive part equals the original polynomial.

Examples:
In> poly := 2*x^2 + 4*x;
Out> 2*x^2+4*x;
In> c := Content(poly);
Out> 2*x;
In> pp := PrimitivePart(poly);
Out> x+2;
In> Expand(pp*c);
Out> 2*x^2+4*x;

See also:
Content .


LeadingCoef -- leading coefficient of a polynomial

Standard library
Calling format:
LeadingCoef(poly)
LeadingCoef(poly, var)

Parameters:
poly -- a polynomial

var -- a variable

Description:
This function returns the leading coefficient of "poly", regarded as a polynomial in the variable "var". The leading coefficient is the coefficient of the term of highest degree. If only one variable appears in the expression "poly", it is obvious that it should be regarded as a polynomial in this variable and the first calling sequence may be used.

Examples:
In> poly := 2*x^2 + 4*x;
Out> 2*x^2+4*x;
In> lc := LeadingCoef(poly);
Out> 2;
In> m := Monic(poly);
Out> x^2+2*x;
In> Expand(lc*m);
Out> 2*x^2+4*x;

In> LeadingCoef(2*a^2 + 3*a*b^2 + 5, a);
Out> 2;
In> LeadingCoef(2*a^2 + 3*a*b^2 + 5, b);
Out> 3*a;

See also:
Coef , Monic .


Monic -- monic part of a polynomial

Standard library
Calling format:
Monic(poly)
Monic(poly, var)

Parameters:
poly -- a polynomial

var -- a variable

Description:
This function returns the monic part of "poly", regarded as a polynomial in the variable "var". The monic part of a polynomial is the quotient of this polynomial by its leading coefficient. So the leading coefficient of the monic part is always one. If only one variable appears in the expression "poly", it is obvious that it should be regarded as a polynomial in this variable and the first calling sequence may be used.

Examples:
In> poly := 2*x^2 + 4*x;
Out> 2*x^2+4*x;
In> lc := LeadingCoef(poly);
Out> 2;
In> m := Monic(poly);
Out> x^2+2*x;
In> Expand(lc*m);
Out> 2*x^2+4*x;

In> Monic(2*a^2 + 3*a*b^2 + 5, a);
Out> a^2+(a*3*b^2)/2+5/2;
In> Monic(2*a^2 + 3*a*b^2 + 5, b);
Out> b^2+(2*a^2+5)/(3*a);

See also:
LeadingCoef .


SquareFree -- return the square-free part of polynomial

Standard library
Calling format:
SquareFree(p)

Parameters:
p - a polynomial in x

Description:
Given a polynomial

p=p[1]^n[1]*...*p[m]^n[m]

with irreducible polynomials p[i], return the square-free version part (with all the factors having multiplicity 1):

p[1]*...*p[m]

Examples:
In> Expand((x+1)^5)
Out> x^5+5*x^4+10*x^3+10*x^2+5*x+1;
In> SquareFree(%)
Out> (x+1)/5;
In> Monic(%)
Out> x+1;

See also:
FindRealRoots , NumRealRoots , MinimumBound , MaximumBound , Factor .


Div and Mod for polynomials

Standard library
Div and Mod are also defined for polynomials.

See also:
Div , Mod .


Horner -- convert a polynomial into the Horner form

Standard library
Calling format:
Horner(expr, var)

Parameters:
expr -- a polynomial in "var"

var -- a variable

Description:
This command turns the polynomial "expr", considered as a univariate polynomial in "var", into Horner form. A polynomial in normal form is an expression such as

c[0]+c[1]*x+...+c[n]*x^n.

If one converts this polynomial into Horner form, one gets the equivalent expression

(...(c[n]*x+c[n-1])*x+...+c[1])*x+c[0].

Both expression are equal, but the latter form gives a more efficient way to evaluate the polynomial as the powers have disappeared.

Examples:
In> expr1:=Expand((1+x)^4)
Out> x^4+4*x^3+6*x^2+4*x+1;
In> Horner(expr1,x)
Out> (((x+4)*x+6)*x+4)*x+1;

See also:
Expand , ExpandBrackets , EvaluateHornerScheme .


ExpandBrackets -- expand all brackets

Standard library
Calling format:
ExpandBrackets(expr)

Parameters:
expr -- an expression

Description:
This command tries to expand all the brackets by repeatedly using the distributive laws a*(b+c)=a*b+a*c and (a+b)*c=a*c+b*c. It goes further than Expand, in that it expands all brackets.

Examples:
In> Expand((a-x)*(b-x),x)
Out> x^2-(b+a)*x+a*b;
In> Expand((a-x)*(b-x),{x,a,b})
Out> x^2-(b+a)*x+b*a;
In> ExpandBrackets((a-x)*(b-x))
Out> a*b-x*b+x^2-a*x;

See also:
Expand .


EvaluateHornerScheme -- fast evaluation of polynomials

Standard library
Calling format:
EvaluateHornerScheme(coeffs,x)

Parameters:
coeffs -- a list of coefficients

x -- expression

Description:
This function evaluates a polynomial given as a list of its coefficients, using the Horner scheme. The list of coefficients starts with the 0-th power.

Example:
In> EvaluateHornerScheme({a,b,c,d},x)
Out> a+x*(b+x*(c+x*d));

See also:
Horner .