Completing the square

Animation depicting the process of completing the square. (Details, animated GIF version)

In elementary algebra, completing the square is a technique for converting a quadratic polynomial of the form

ax^{2}+bx+c

to the form

a(x-h)^{2}+k

for some values of h and k.

In other words, completing the square places a perfect square trinomial inside of a quadratic expression.

Completing the square is used in

solving quadratic equations,
deriving the quadratic formula,
graphing quadratic functions,
evaluating integrals in calculus, such as Gaussian integrals with a linear term in the exponent,^[1]
finding Laplace transforms.^[2]^[3]

In mathematics, completing the square is often applied in any computation involving quadratic polynomials.

History[edit]

The technique of completing the square was known in the Old Babylonian Empire.^[4]

Muhammad ibn Musa Al-Khwarizmi, a famous polymath who wrote the early algebraic treatise Al-Jabr, used the technique of completing the square to solve quadratic equations.^[5]

Overview[edit]

Background[edit]

The formula in elementary algebra for computing the square of a binomial is:

(x+p)^{2}\,=\,x^{2}+2px+p^{2}.

For example:

{\begin{alignedat}{2}(x+3)^{2}\,&=\,x^{2}+6x+9&&(p=3)\\[3pt](x-5)^{2}\,&=\,x^{2}-10x+25\qquad &&(p=-5).\end{alignedat}}

In any perfect square, the coefficient of x is twice the number p, and the constant term is equal to p².

Basic example[edit]

Consider the following quadratic polynomial:

x^{2}+10x+28.

This quadratic is not a perfect square, since 28 is not the square of 5:

(x+5)^{2}\,=\,x^{2}+10x+25.

However, it is possible to write the original quadratic as the sum of this square and a constant:

x^{2}+10x+28\,=\,(x+5)^{2}+3.

This is called completing the square.

General description[edit]

Given any monic quadratic

x^{2}+bx+c,

it is possible to form a square that has the same first two terms:

\left(x+{\tfrac {1}{2}}b\right)^{2}\,=\,x^{2}+bx+{\tfrac {1}{4}}b^{2}.

This square differs from the original quadratic only in the value of the constant term. Therefore, we can write

x^{2}+bx+c\,=\,\left(x+{\tfrac {1}{2}}b\right)^{2}+k,

where

k=c-{\frac {b^{2}}{4}}

. This operation is known as completing the square. For example:

{\begin{alignedat}{1}x^{2}+6x+11\,&=\,(x+3)^{2}+2\\[3pt]x^{2}+14x+30\,&=\,(x+7)^{2}-19\\[3pt]x^{2}-2x+7\,&=\,(x-1)^{2}+6.\end{alignedat}}

Non-monic case[edit]

Given a quadratic polynomial of the form

ax^{2}+bx+c

it is possible to factor out the coefficient a, and then complete the square for the resulting monic polynomial.

Example:

{\begin{aligned}3x^{2}+12x+27&=3[x^{2}+4x+9]\\&{}=3\left[(x+2)^{2}+5\right]\\&{}=3(x+2)^{2}+3(5)\\&{}=3(x+2)^{2}+15\end{aligned}}

This process of factoring out the coefficient a can further be simplified by only factorising it out of the first 2 terms. The integer at the end of the polynomial does not have to be included.

Example:

{\begin{aligned}3x^{2}+12x+27&=3\left[x^{2}+4x\right]+27\\[1ex]&{}=3\left[(x+2)^{2}-4\right]+27\\[1ex]&{}=3(x+2)^{2}+3(-4)+27\\[1ex]&{}=3(x+2)^{2}-12+27\\[1ex]&{}=3(x+2)^{2}+15\end{aligned}}

This allows the writing of any quadratic polynomial in the form

a(x-h)^{2}+k.

Formula[edit]

Scalar case[edit]

The result of completing the square may be written as a formula. In the general case, one has^[6]

ax^{2}+bx+c=a(x-h)^{2}+k,

with

h=-{\frac {b}{2a}}\quad {\text{and}}\quad k=c-ah^{2}=c-{\frac {b^{2}}{4a}}.

In particular, when $a = 1$ , one has

x^{2}+bx+c=(x-h)^{2}+k,

with

h=-{\frac {b}{2}}\quad {\text{and}}\quad k=c-h^{2}=c-{\frac {b^{2}}{4}}.

By solving the equation $a(x-h)^{2}+k=0$ in terms of $x-h,$ and reorganizing the resulting expression, one gets the quadratic formula for the roots of the quadratic equation:

x={\frac {-b\pm {\sqrt {b^{2}-4ac}}}{2a}}.

Matrix case[edit]

The matrix case looks very similar:

x^{\mathrm {T} }Ax+x^{\mathrm {T} }b+c=(x-h)^{\mathrm {T} }A(x-h)+k

where

{\textstyle h=-{\frac {1}{2}}A^{-1}b}

and

{\textstyle k=c-{\frac {1}{4}}b^{\mathrm {T} }A^{-1}b}

. Note that

A

has to be symmetric.

If $A$ is not symmetric the formulae for $h$ and $k$ have to be generalized to:

h=-(A+A^{\mathrm {T} })^{-1}b\quad {\text{and}}\quad k=c-h^{\mathrm {T} }Ah=c-b^{\mathrm {T} }(A+A^{\mathrm {T} })^{-1}A(A+A^{\mathrm {T} })^{-1}b

Relation to the graph[edit]

Graphs of quadratic functions shifted to the right by h = 0, 5, 10, and 15.

Graphs of quadratic functions shifted upward by k = 0, 5, 10, and 15.

Graphs of quadratic functions shifted upward and to the right by 0, 5, 10, and 15.

In analytic geometry, the graph of any quadratic function is a parabola in the xy-plane. Given a quadratic polynomial of the form

a(x-h)^{2}+k

the numbers h and k may be interpreted as the Cartesian coordinates of the vertex (or stationary point) of the parabola. That is, h is the x-coordinate of the axis of symmetry (i.e. the axis of symmetry has equation x = h), and k is the minimum value (or maximum value, if a < 0) of the quadratic function.

One way to see this is to note that the graph of the function $f (x) = x 2$ is a parabola whose vertex is at the origin (0, 0). Therefore, the graph of the function $f (x - h) = (x - h) 2$ is a parabola shifted to the right by h whose vertex is at (h, 0), as shown in the top figure. In contrast, the graph of the function $f (x) + k = x 2 + k$ is a parabola shifted upward by $k$ whose vertex is at $(0, k)$ , as shown in the center figure. Combining both horizontal and vertical shifts yields $f (x - h) + k = (x - h) 2 + k$ is a parabola shifted to the right by $h$ and upward by $k$ whose vertex is at $(h, k)$ , as shown in the bottom figure.

Solving quadratic equations[edit]

Completing the square may be used to solve any quadratic equation. For example:

x^{2}+6x+5=0.

The first step is to complete the square:

(x+3)^{2}-4=0.

Next we solve for the squared term:

(x+3)^{2}=4.

Then either

x+3=-2\quad {\text{or}}\quad x+3=2,

and therefore

x=-5\quad {\text{or}}\quad x=-1.

This can be applied to any quadratic equation. When the x² has a coefficient other than 1, the first step is to divide out the equation by this coefficient: for an example see the non-monic case below.

Irrational and complex roots[edit]

Unlike methods involving factoring the equation, which is reliable only if the roots are rational, completing the square will find the roots of a quadratic equation even when those roots are irrational or complex. For example, consider the equation

x^{2}-10x+18=0.

Completing the square gives

(x-5)^{2}-7=0,

so

(x-5)^{2}=7.

Then either

x-5=-{\sqrt {7}}\quad {\text{or}}\quad x-5={\sqrt {7}}.

In terser language:

x-5=\pm {\sqrt {7}},

so

x=5\pm {\sqrt {7}}.

Equations with complex roots can be handled in the same way. For example:

{\begin{aligned}x^{2}+4x+5&=0\\[6pt](x+2)^{2}+1&=0\\[6pt](x+2)^{2}&=-1\\[6pt]x+2&=\pm i\\[6pt]x&=-2\pm i.\end{aligned}}

Non-monic case[edit]

For an equation involving a non-monic quadratic, the first step to solving them is to divide through by the coefficient of x². For example:

{\begin{array}{c}2x^{2}+7x+6\,=\,0\\[6pt]x^{2}+{\tfrac {7}{2}}x+3\,=\,0\\[6pt]\left(x+{\tfrac {7}{4}}\right)^{2}-{\tfrac {1}{16}}\,=\,0\\[6pt]\left(x+{\tfrac {7}{4}}\right)^{2}\,=\,{\tfrac {1}{16}}\\[6pt]x+{\tfrac {7}{4}}={\tfrac {1}{4}}\quad {\text{or}}\quad x+{\tfrac {7}{4}}=-{\tfrac {1}{4}}\\[6pt]x=-{\tfrac {3}{2}}\quad {\text{or}}\quad x=-2.\end{array}}

Applying this procedure to the general form of a quadratic equation leads to the quadratic formula.

Other applications[edit]

Integration[edit]

Completing the square may be used to evaluate any integral of the form

\int {\frac {dx}{ax^{2}+bx+c}}

using the basic integrals

\int {\frac {dx}{x^{2}-a^{2}}}={\frac {1}{2a}}\ln \left|{\frac {x-a}{x+a}}\right|+C\quad {\text{and}}\quad \int {\frac {dx}{x^{2}+a^{2}}}={\frac {1}{a}}\arctan \left({\frac {x}{a}}\right)+C.

For example, consider the integral

\int {\frac {dx}{x^{2}+6x+13}}.

Completing the square in the denominator gives:

\int {\frac {dx}{(x+3)^{2}+4}}\,=\,\int {\frac {dx}{(x+3)^{2}+2^{2}}}.

This can now be evaluated by using the substitution u = x + 3, which yields

\int {\frac {dx}{(x+3)^{2}+4}}\,=\,{\frac {1}{2}}\arctan \left({\frac {x+3}{2}}\right)+C.

Complex numbers[edit]

Consider the expression

|z|^{2}-b^{*}z-bz^{*}+c,

where z and b are complex numbers, z^* and b^* are the complex conjugates of z and b, respectively, and c is a real number. Using the identity |u|² = uu^* we can rewrite this as

|z-b|^{2}-|b|^{2}+c,

which is clearly a real quantity. This is because

{\begin{aligned}|z-b|^{2}&{}=(z-b)(z-b)^{*}\\&{}=(z-b)(z^{*}-b^{*})\\&{}=zz^{*}-zb^{*}-bz^{*}+bb^{*}\\&{}=|z|^{2}-zb^{*}-bz^{*}+|b|^{2}.\end{aligned}}

As another example, the expression

ax^{2}+by^{2}+c,

where a, b, c, x, and y are real numbers, with a > 0 and b > 0, may be expressed in terms of the square of the absolute value of a complex number. Define

z={\sqrt {a}}\,x+i{\sqrt {b}}\,y.

Then

{\begin{aligned}|z|^{2}&{}=zz^{*}\\[1ex]&{}=\left({\sqrt {a}}\,x+i{\sqrt {b}}\,y\right)\left({\sqrt {a}}\,x-i{\sqrt {b}}\,y\right)\\[1ex]&{}=ax^{2}-i{\sqrt {ab}}\,xy+i{\sqrt {ba}}\,yx-i^{2}by^{2}\\[1ex]&{}=ax^{2}+by^{2},\end{aligned}}

so

ax^{2}+by^{2}+c=|z|^{2}+c.

Idempotent matrix[edit]

A matrix M is idempotent when M² = M. Idempotent matrices generalize the idempotent properties of 0 and 1. The completion of the square method of addressing the equation

a^{2}+b^{2}=a,

shows that some idempotent 2×2 matrices are parametrized by a circle in the (a,b)-plane:

The matrix ${\begin{pmatrix}a&b\\b&1-a\end{pmatrix}}$ will be idempotent provided $a^{2}+b^{2}=a,$ which, upon completing the square, becomes

(a-{\tfrac {1}{2}})^{2}+b^{2}={\tfrac {1}{4}}.

In the (a,b)-plane, this is the equation of a circle with center (1/2, 0) and radius 1/2.

Geometric perspective[edit]

Consider completing the square for the equation

x^{2}+bx=a.

Since x² represents the area of a square with side of length x, and bx represents the area of a rectangle with sides b and x, the process of completing the square can be viewed as visual manipulation of rectangles.

Simple attempts to combine the x² and the bx rectangles into a larger square result in a missing corner. The term (b/2)² added to each side of the above equation is precisely the area of the missing corner, whence derives the terminology "completing the square".^[7]

A variation on the technique[edit]

As conventionally taught, completing the square consists of adding the third term, v² to

u^{2}+2uv

to get a square. There are also cases in which one can add the middle term, either 2uv or −2uv, to

u^{2}+v^{2}

to get a square.

Example: the sum of a positive number and its reciprocal[edit]

By writing

{\begin{aligned}x+{1 \over x}&{}=\left(x-2+{1 \over x}\right)+2\\&{}=\left({\sqrt {x}}-{1 \over {\sqrt {x}}}\right)^{2}+2\end{aligned}}

we show that the sum of a positive number x and its reciprocal is always greater than or equal to 2. The square of a real expression is always greater than or equal to zero, which gives the stated bound; and here we achieve 2 just when x is 1, causing the square to vanish.

Example: factoring a simple quartic polynomial[edit]

Consider the problem of factoring the polynomial

x^{4}+324.

This is

(x^{2})^{2}+(18)^{2},

so the middle term is 2(x²)(18) = 36x². Thus we get

{\begin{aligned}x^{4}+324&{}=(x^{4}+36x^{2}+324)-36x^{2}\\&{}=(x^{2}+18)^{2}-(6x)^{2}={\text{a difference of two squares}}\\&{}=(x^{2}+18+6x)(x^{2}+18-6x)\\&{}=(x^{2}+6x+18)(x^{2}-6x+18)\end{aligned}}

(the last line being added merely to follow the convention of decreasing degrees of terms).

The same argument shows that $x^{4}+4a^{4}$ is always factorizable as

x^{4}+4a^{4}=\left(x^{2}+2ax+2a^{2}\right)\left(x^{2}-2ax+2a^{2}\right)

(Also known as Sophie Germain's identity).

Completing the cube[edit]

"Completing the square" consists to remark that the two first terms of a quadratic polynomial are also the first terms of the square of a linear polynomial, and to use this for expressing the quadratic polynomial as the sum of a square and a constant.

Completing the cube is a similar technique that allows to transform a cubic polynomial into a cubic polynomial without term of degree two.

More precisely, if