### Polynomials: Factor and Remainder Theorem

In Algebra, we regularly come across the polynomials. The skill in solving algebraic operations of polynomials is very important in mathematics.

If you need to revise on the basic of algebra, you can look at it here.

__The definition__

\( {\small P(x) \ = \ a_{n} x^{n} + a_{n-1} x^{n-1} + a_{n-2} x^{n-2} + … + a_{0} }\)

\(\\[5pt] {\small n \ }\) is a non-negative integer. It is the degree or the order of the polynomial.

\(\\[5pt] {\small x \ }\) is the variable of the polynomial.

\(\\[5pt] {\small a_{n}, a_{n-1}, a_{n-2}, … , a_{0} \ }\) are the coefficients of each term in \({ \small x \ }\) from the highest power to the lowest power.

Here are some of the examples:

*1. \(\\[5pt]\) Linear polynomial or polynomial of degree 1*

\( \hspace{1em} {\small P(x) \ = \ ax \ + \ b }\)

e.g.: \({\small P(x) \ = \ 2x \ + \ 3 }\)

*2. \(\\[5pt]\) Quadratic polynomial or polynomial of degree 2*

\( \hspace{1em} {\small P(x) \ = \ ax^{2} + bx + c }\)

e.g.: \({\small P(x) \ = \ 3x^{2} + 2x + 3 }\)

*3. \(\\[5pt]\) Cubic polynomial or polynomial of degree 3*

\( \hspace{1em} {\small P(x) \ = \ ax^{3} + bx^{2} + cx + d }\)

e.g.: \({\small P(x) \ = \ 3x^{3} + 2x^2 + 3x + 5 }\)

*4. \(\\[5pt]\) Quartic polynomial or polynomial of degree 4*

\( \hspace{1em} {\small P(x) \ = \ ax^{4} + bx^{3} + cx^{2} + dx + e }\)

e.g.: \({\small P(x) \ = \ 5x^{4} + 2x^{3} + 3x^2 + x + 6 }\)

__The addition and subtraction of polynomials__

Collect all **the like terms** and simply the expression by adding or subtracting **the like terms**.

e.g.:

\( \hspace{1em} {\small P(x) \ = \ 2x^{2} + 3x + 4 }\)

\( \hspace{1em} {\small Q(x) \ = \ x^{2} \ – \ 2x + 3 }\)

\( \hspace{1em} {\small P(x) \ + \ Q(x) }\)

\( \hspace{1.5em} {\small = \ (2x^{2} + 3x + 4) + (x^{2} \ – \ 2x + 3) }\)

\( \hspace{1.5em} {\small = \ (2x^{2} + x^{2}) + (3x \ – \ 2x) + (4 + 3) }\)

\( \hspace{1.5em} {\small = \ 3x^{2} + x + 7 }\)

\( \hspace{1em} {\small P(x) \ – \ Q(x) }\)

\( \hspace{1.5em} {\small = \ (2x^{2} + 3x + 4) \ – \ (x^{2} \ – \ 2x + 3) }\)

\( \hspace{1.5em} {\small = \ (2x^{2} \ – \ x^{2}) + (3x \ + \ 2x) + (4 \ – \ 3) }\)

\( \hspace{1.5em} {\small = \ x^{2} + 5x + 1 }\)

__The multiplication of polynomials__

Use **the distributive law** by multiplying each term.

e.g.:

\( \hspace{1em} {\small P(x) \ = \ 2x^{2} + 3x + 4 }\)

\( \hspace{1em} {\small Q(x) \ = \ x^{2} \ – \ 2x + 3 }\)

\( \hspace{1em} {\small P(x) \ \times \ Q(x) }\)

\( \hspace{1.5em} {\small = \ 2x^{4} + (3x^{3} \ – \ 4x^{3}) + (6x^{2} \ – \ 6x^{2} + 4x^{2}) }\)

\(\\[8pt] \hspace{2.5em} {\small + \ (9x \ – \ 8x) + 12 }\)

\( \hspace{1.5em} {\small = \ 2x^{4} \ – \ x^{3} + 4x^{2} + x + 12 }\)

__The division of polynomials__

We’ll use a simple analogy of **long division** of a number to illustrate the polynomial division.

Just as an example, what is the result of 7 divided by 3?

So, \(\hspace{1em} {\large\frac{7}{3}} \ = \ 2 \ + \ {\large\frac{1}{3}} \)

Or, we can conveniently write the above result as,

\(\hspace{1.5em} 7 \ = \ 2 \times 3 \ + \ 1 \ \)

Then, in terms of polynomial division,

\( \hspace{1em} {\large\frac{P(x)}{D(x)}} \ = \ Q(x) \ + {\large\frac{R(x)}{D(x)}} \)

or in its general form:

\( \hspace{1em} P(x) \ = \ D(x) \times Q(x) + R(x) \)

with,

P(x) is the polynomial to be divided with or the dividend,

D(x) is the divisor,

Q(x) is the quotient and

R(x) is the remainder.

The process of finding the quotient Q(x) and the remainder R(x) can be done similarly with **polynomial long division**.

Here is an example,

\(\hspace{1em} {\Large\frac{x^{2} \ – \ 4x \ – \ 3}{x \ + \ 1}} \ = \ ? \)

*Step 1. Divide the highest power of the polynomial P(x) with the highest power of the divisor D(x).*

*Step 2. Multiply the result we get in the quotient Q(x) from Step 1 with the divisor D(x).*

*Step 3. Subtract the polynomial P(x) from the result in Step 2.*

*Step 4. Repeat the process from Step 1 to the next available highest power of polynomial P(x) until we are left with only the remainder.*

Now, one important thing to remember is that the degree of the remainder *R(x)* is **at most one fewer than the order of the divisor D(X)**.

For example, if we have a linear divisor \({\small \ ax \ + \ b \ }\) then the remainder is a constant.

If we have a quadratic divisor \({\small \ ax^{2} \ + \ bx \ + \ c \ }\) then the remainder is a linear polynomial and so on.

By knowing that, we’ll know **when to stop** the process of multiplying back the quotient.

__Factor Theorem__

If \({\small \ (ax \ + \ b) \ }\) is **a linear factor** of a polynomial *P(x)* then \({\small \ P({\large\frac{-b}{a}}) \ = \ 0 }\).

e.g.: Show that \({\small \ (x \ – \ 2) \ }\) is a linear factor of a polynomial \({\small P(x) \ = \ x^{4} \ – \ 5x^{2} + 2x }\).

*Solution: If \({\small \ (x \ – \ 2) \ }\) is a linear factor, then according to the factor theorem \({\small \ P(2) \ }\) must be equal to zero.*

*We’ll try by substituting the value of \({\small \ x \ = \ 2 }\),*

*\(\hspace{1.5em} {\small P(2) \ = \ ({2})^{4} \ – \ 5({2})^{2} + 2(2) }\) \(\hspace{3.2em} {\small \ = \ 16 \ – \ 20 + 4 }\) \(\hspace{3.2em} {\small \ = \ 0 }\)*

*Therefore, \({\small \ (x \ – \ 2) \ }\) is a linear factor of \({\small \ P(x) \ = \ x^{4} \ – \ 5x^{2} + 2x }\).*

Another great use of factor theorem is when we want to factorise a higher order polynomial or the roots of a higher order polynomial equation.

We can use **the constant term** of the higher order polynomial and quickly substituting the value of each factors of the constant term.

If any of the results equals to zero then by factor theorem we can find its linear factor(s).

The other factors can then be found by applying polynomial long division.

You can study some of the examples below to fully understand the concept.

__Remainder Theorem__

If a polynomial *P(x)* is divided by **a linear divisor** \({\small \ (ax \ + \ b) \ }\) then \({\small \ P({\large\frac{-b}{a}}) \ }\) is the remainder.

e.g.: Find the remainder when a polynomial \({\small \ P(x) \ = \ x^{4} \ – \ 2x^{3} + 3x^{2} \ – \ 8 \ }\) is divided by \({\small \ (x \ – \ 1) }\).

*Solution: According to the remainder theorem, the remainder is \({\small \ P(1) \ }\),*

*\(\hspace{1.5em} {\small P(1) \ = \ (1)^{4} \ – \ 2(1)^{3} + 3(1)^{2} \ – \ 8 }\) \(\hspace{3.2em} {\small \ = \ 1 \ – \ 2 + 3 \ – \ 8 }\) \(\hspace{3.2em} {\small \ = \ -6 }\)*

*Therefore, the remainder of \({\small \ P(x) \ = \ x^{4} \ – \ 2x^{3} + 3x^{2} \ – \ 8 \ }\) is \({\small \ -6 \ }\) when it is divided by \({\small \ (x \ – \ 1) }\).*

Try some of the examples below and if you need any help, just look at the solution I have written. Cheers ! =) .

\(\\[1pt]\)

EXAMPLE:

\(\\[1pt]\)

\({\small 2.\enspace}\) Find the value of \({\small \ k \ }\) if \({\small \ (x \ – \ 1) \ }\) is a factor of \({\small \ {k}^{2}{x}^{4} \ – \ 3k{x}^{2} + 2 }\).

\(\\[1pt]\)

\({\small 3.\enspace}\) This is an example of the aplication of

**the factor theorem**. We would try to find the roots of higher order polynomials.

\(\\[1pt]\)

Factorise \({\small \ 2{𝑥}^{3} + 9{𝑥}^{2} + 7{𝑥} \ − \ 6 \ }\) completely and hence find all the roots of the polynomial.

\(\\[1pt]\)

\({\small 4.\enspace}\) Given that a polynomial \({\small \ p(x) \ = \ {𝑥}^{3} + a{𝑥}^{2} + b{𝑥} \ − \ 3 \ }\) when divided by \({\small \ (x + 1) \ }\) and \({\small \ (x \ – \ 1) }\), the remainders are -9 and 1 respectively. Find the values of

*a*and

*b*.

\(\\[1pt]\)

\({\small 5.\enspace}\) Continuing from the same question in example 4, find the reminder when the polynomial \({\small \ p(x) \ }\) is divided by \({\small \ ({x}^{2} \ – \ 1) }\).

\(\\[1pt]\)

\({\small 6.\enspace}\)

**9709/21/w19**

The polynomial

*p(x)*is defined by:

\(\\[1pt]\)

\(\hspace{3em} {\small p(x) \ = \ a{x}^{3} + a{x}^{2} \ − \ 15x \ − \ 18}\),

\(\\[1pt]\)

where

*a*is a constant. It is given that (

*x*− 2) is a factor of

*p(x)*.

\({\small (\textrm{i}).\hspace{0.7em}}\) Find the value of

*a*.

\({\small (\textrm{ii}).\hspace{0.6em}}\) Using this value of

*a*, factorise

*p(x)*completely.

\({\small (\textrm{iii}).\hspace{0.5em}}\) Hence solve the equation \({\small \ p(e^{\sqrt{y}}) \ = \ 0}\), giving the answer correct to 2 significant figures.

\(\\[1pt]\)

PRACTICE MORE WITH THESE QUESTIONS BELOW!

\({\small 1.\enspace}\) The polynomial p(*x*) is defined by

\( \hspace{3em} {\small \ p(x) \ = \ 6{x}^{3} + a{x}^{2} + 9{x} + b }\),

where *a* and *b* are constants. It is given that \({\small \ (x \ – \ 2) \ }\) and \({\small \ (2x + 1) }\) are factors of p(*x*). Find the values of *a* and *b*.

\({\small 2. \enspace}\) The polynomial p(*x*) is defined by

\( \hspace{3em} {\small \ p(x) \ = \ 6{x}^{3} + a{x}^{2} \ – \ 4{x} \ – \ 3 }\),

where *a* is a constant. It is given that \({\small \ (x + 3) \ }\) is a factor of p(*x*).

\({\small\hspace{1.2em} (\textrm{a}).\hspace{0.8em}}\) Find the value of *a*.

\({\small\hspace{1.2em} (\textrm{b}).\hspace{0.8em}}\) Using this value of *a*, factorise p(*x*) completely.

\({\small 3. \enspace}\) Find the quotient and remainder when \({\small \ 6{x}^{4} + {x}^{3} \ − \ {x}^{2} + 5x \ − \ 6 \ }\) is divided by \( {\small \ (2{x}^{2} \ − \ x + 1) }\).

\({\small 4. \enspace}\) The polynomial f(*x*) is defined by

\( \hspace{3em} {\small \ f(x) \ = \ {x}^{4} \ – \ 3{x}^{3} + 5{x}^{2} \ – \ 6{x} + 11 }\),

Find the quotient and remainder when f(*x*) is divided by \({\small \ ({x}^2 + 2) }\).

\({\small 5. \enspace}\) The polynomial \({\small \ 6{x}^{3} + a{x}^{2} + b{x} \ − \ 2 }\), where *a* and *b* are constants, is denoted by p(*x*). It is given that \({\small \ (2x + 1) }\) is a factor of p(*x*) and that when p(*x*) is divided by \({\small \ (x + 2) \ }\) the remainder is −24. Find the values of *a* and *b*.

\({\small 6. \enspace}\) The polynomial \({\small \ {x}^{4} + 3{x}^{3} + ax + b }\), where *a* and *b* are constants, is denoted by p(*x*). When p(*x*) is divided by \({\small \ {x}^{2} + x \ − \ 1 \ }\) the remainder is \({\small \ 2x + 3}\). Find the values of *a* and *b*.

\({\small 7. \enspace}\) The cubic polynomial f(*x*) is defined by \({\small \ f(x) \ = \ {x}^{3} + a{x}^{2} + 14x + a + 1 }\), where *a* is a constant. It is given that \({\small \ (x + 2) \ }\) is a factor of f(*x*). Use the factor theorem to find the value of *a* and hence factorise f(*x*) completely.

\({\small 8. \enspace}\) \({\small (\textrm{i}).\hspace{0.7em}}\) Find the quotient when \({\small \ {x}^{4} \ − \ 2{x}^{3} + 8{x}^{2} \ − \ 12x + 13 \ }\) is divided by \({\small \ {x}^{2} + 6 \ }\) and show that the remainder is 1.

\({\small\hspace{1.3em}(\textrm{ii}).\hspace{0.7em}}\) Show that the equation \({\small \ {x}^{4} \ − \ 2{x}^{3} + 8{x}^{2} \ − \ 12x + 12 \ = \ 0 \ }\) has no real roots.

\({\small 9. \enspace}\) The polynomial \({\small \ {x}^{4} + {x}^{3} + ax + b}\), where *a* and *b* are constants, is divisible by \({\small \ {x}^{2} \ − \ x + 1}\). Find the values of *a* and *b*.

\({\small 10.\enspace}\) The polynomial p(*x*) is defined by \({\small \ p(x) \ = \ 4{x}^{3} + 4{x}^{2} \ − \ 29x \ − \ 15 }\).

\({\small\hspace{2.8em}(\textrm{i}).\hspace{0.7em}}\) Use the factor theorem to show that \({\small \ x + 3 \ }\) is a factor of p(*x*).

\({\small\hspace{2.8em}(\textrm{ii}).\hspace{0.7em}}\) Factorise p(*x*) completely.

As always, if you have any particular questions to discuss, leave it in the comment section below. Cheers =) .