# Functional equation

In mathematics, a functional equation is any equation that specifies a function in implicit form. Often, the equation relates the value of a function (or functions) at some point with its values at other points. For instance, properties of functions can be determined by considering the types of functional equations they satisfy. The term functional equation usually refers to equations that cannot be simply reduced to algebraic equations.

## Examples

• The functional equation
$f(s)=2^{s}\pi ^{s-1}\sin \left({\frac {\pi s}{2}}\right)\Gamma (1-s)f(1-s)$ is satisfied by the Riemann zeta function. The capital Template:Mvar denotes the gamma function.
• The gamma function is the unique solution of the following system of three equations:
$f(x)={f(x+1) \over x}\,\!$ $f(y)f\left(y+{\frac {1}{2}}\right)={\frac {\sqrt {\pi }}{2^{2y-1}}}f(2y)$ $f(z)f(1-z)={\pi \over \sin(\pi z)}\,\!\,\,\,$ (Euler's reflection formula)
• The functional equation
$f\left({az+b \over cz+d}\right)=(cz+d)^{k}f(z)\,\!$ where a, b, c, d are integers satisfying adbc = 1, i.e. ${\begin{vmatrix}a&b\\c&d\end{vmatrix}}$ = 1, defines Template:Mvar to be a modular form of order Template:Mvar.
• Miscellaneous examples, not necessarily involving standard or named functions:
$f(x+y)=f(x)+f(y)\,\!$ (Cauchy functional equation)

Exponentiating,

$f(x+y)=f(x)f(y),\,\!$ satisfied by all exponential functions
$f(xy)=f(x)+f(y)\,\!$ , satisfied by all logarithmic functions
$f(xy)=f(x)f(y)\,\!$ , satisfied by all powers
$f(x+y)+f(x-y)=2[f(x)+f(y)]\,\!$ (quadratic equation or parallelogram law)
$f((x+y)/2)=(f(x)+f(y))/2\,\!$ (Jensen)
$g(x+y)+g(x-y)=2[g(x)g(y)]\,\!$ (d'Alembert)
$f(h(x))=h(x+1)\,\!$ (Abel equation)
$f(h(x))=cf(x)\,\!$ (Schröder's equation).
$f(h(x))=(f(x))^{c}\,\!$ (Böttcher's equation).
$f(x+y)=f(x)g(y)+f(y)g(x)\,\!$ (sine addition formula).
$g(x+y)=g(x)g(y)-f(y)f(x)\,\!$ (cosine addition formula).
$f(xy)=\sum g_{l}(x)h_{l}(y)\,\!$ (Levi-Civita).

• A simple form of functional equation is a recurrence relation. This, formally speaking, involves a unspecified functions on integers and also shift operators. One such example of a recurrence relation is
$a(n)=3a(n-1)+4a(n-2)\,\!$ • The commutative and associative laws are functional equations. When the associative law is expressed in its familiar form, one lets some symbol between two variables represent a binary operation,
$(a\circ b)\circ c=a\circ (b\circ c)~.$ But if we wrote ƒ(ab) instead of a ○ b then the associative law would look more like what one conventionally thinks of as a functional equation,

$f(f(a,b),c)=f(a,f(b,c)).\,\!$ One feature that all of the examples listed above share in common is that, in each case, two or more known functions (sometimes multiplication by a constant, sometimes addition of two variables, sometimes the identity function) are inside the argument of the unknown functions to be solved for.

When it comes to asking for all solutions, it may be the case that conditions from mathematical analysis should be applied; for example, in the case of the Cauchy equation mentioned above, the solutions that are continuous functions are the 'reasonable' ones, while other solutions that are not likely to have practical application can be constructed (by using a Hamel basis for the real numbers as vector space over the rational numbers). The Bohr–Mollerup theorem is another well-known example.

## Solving functional equations

Solving functional equations can be very difficult, but there are some common methods of solving them. For example, in dynamic programming a variety of successive approximation methods are used to solve Bellman's functional equation, including methods based on fixed point iterations.

A main method of solving elementary functional equations is substitution. It is often useful to prove surjectivity or injectivity and prove oddness or evenness, if possible. It is also useful to guess possible solutions. Induction is a useful technique to use when the function is only defined for rational or integer values.

A discussion of involutory functions is topical. For example, consider the function

$f(x)=1-x\,.$ Composing Template:Mvar with itself gives Babbage's functional equation (1820),

$f(f(x))=1-(1-x)=x\,.$ Several other functions also satisfy this functional equation,

$f(f(x))=x~,$ including, beyond f(x) = −x,

$f(x)={\frac {a}{x}}\,,$ and

$f(x)={\frac {b-x}{1+cx}}~,$ which includes the previous three as special cases or limits.

Example 1. Find all functions Template:Mvar that satisfy

$f(x+y)^{2}=f(x)^{2}+f(y)^{2}\,$ for all x,y ∈ ℝ, assuming ƒ is a real-valued function.

Let Template:Mvar = Template:Mvar = 0,

$f(0)^{2}=f(0)^{2}+f(0)^{2}.\,$ So ƒ(0)2 = 0 and ƒ(0) = 0.

Now, let Template:Mvar = −Template:Mvar,

$f(x-x)^{2}=f(x)^{2}+f(-x)^{2}\,$ $f(0)^{2}=f(x)^{2}+f(-x)^{2}\,$ $0=f(x)^{2}+f(-x)^{2}~.$ A square of a real number is nonnegative, and a sum of nonnegative numbers is zero iff both numbers are 0.

So ƒ(x)2 = 0 for all Template:Mvar and ƒ(x) = 0 is the only solution.