These properties are valid only for integers m. For nonintegers the properties are similar but slightly different.

The above property for the powers of the silver ratio is a consequence of a property of the powers of silver means. For the silver mean S of m, the property can be generalized as

${\displaystyle S_{m}^{n}=K_{n}S_{m}+K_{(n-1)}}$ 

where

${\displaystyle K_{n}=mK_{(n-1)}+K_{(n-2)}.}$ 

Using the initial conditions K₀ = 1 and K₁ = m, this recurrence relation becomes

${\displaystyle K_{n}={\frac {S_{m}^{n+1}-{\left(m-S_{m}\right)}^{n+1}}{\sqrt {m^{2}+4}}}.}$ 

The powers of silver means have other interesting properties:

If n is a positive even integer:

${\displaystyle {S_{m}^{n}-\left\lfloor S_{m}^{n}\right\rfloor }=1-S_{m}^{-n}.}$ 

Additionally,

${\displaystyle {1 \over {S_{m}^{4}-\left\lfloor S_{m}^{4}\right\rfloor }}+\left\lfloor S_{m}^{4}-1\right\rfloor =S_{\left(m^{4}+4m^{2}+1\right)}}$ 

${\displaystyle {1 \over {S_{m}^{6}-\left\lfloor S_{m}^{6}\right\rfloor }}+\left\lfloor S_{m}^{6}-1\right\rfloor =S_{\left(m^{6}+6m^{4}+9m^{2}+1\right)}.}$ 

Also,

${\displaystyle S_{m}^{3}=S_{\left(m^{3}+3m\right)}}$ 

${\displaystyle S_{m}^{5}=S_{\left(m^{5}+5m^{3}+5m\right)}}$ 

${\displaystyle S_{m}^{7}=S_{\left(m^{7}+7m^{5}+14m^{3}+7m\right)}}$ 

${\displaystyle S_{m}^{9}=S_{\left(m^{9}+9m^{7}+27m^{5}+30m^{3}+9m\right)}}$ 

${\displaystyle S_{m}^{11}=S_{\left(m^{11}+11m^{9}+44m^{7}+77m^{5}+55m^{3}+11m\right)}.}$ 

In general:

${\displaystyle S_{m}^{2n+1}=S_{\sum _{k=0}^{n}{{2n+1} \over {2k+1}}{{n+k} \choose {2k}}m^{2k+1}}.}$ 

The silver mean S of m also has the property that

${\displaystyle {\frac {1}{S_{m}}}=S_{m}-m}$ 

meaning that the inverse of a silver mean has the same decimal part as the corresponding silver mean.

${\displaystyle S_{m}=a+b}$ 

where a is the integer part of S and b is the decimal part of S, then the following property is true:

${\displaystyle S_{m}^{2}=a^{2}+mb+1.}$ 

Because (for all m greater than 0), the integer part of S_m = m, a = m. For m > 1, we then have

${\displaystyle S_{m}^{2}=ma+mb+1}$ 

${\displaystyle S_{m}^{2}=m(a+b)+1}$ 

${\displaystyle S_{m}^{2}=m\left(S_{m}\right)+1.}$ 

Therefore, the silver mean of m is a solution of the equation

${\displaystyle x^{2}-mx-1=0.}$ 

It may also be useful to note that the silver mean S of −m is the inverse of the silver mean S of m

${\displaystyle {\frac {1}{S_{m}}}=S_{(-m)}=S_{m}-m.}$ 

Another interesting result can be obtained by slightly changing the formula of the silver mean. If we consider a number

${\displaystyle {\frac {n+{\sqrt {n^{2}+4c}}}{2}}=R}$ 

then the following properties are true:

${\displaystyle R-\lfloor R\rfloor ={\frac {c}{R}}}$  if c is real,

${\displaystyle \left({1 \over R}\right)c=R-\lfloor \operatorname {Re} (R)\rfloor }$  if c is a multiple of i.

The silver mean of m is also given by the integral

${\displaystyle S_{m}=\int _{0}^{m}{\left({x \over {2{\sqrt {x^{2}+4}}}}+{{m+2} \over {2m}}\right)}\,dx.}$ 

Another interesting form of the metallic mean is given by

${\displaystyle {\frac {n+{\sqrt {n^{2}+4}}}{2}}=e^{\operatorname {arsinh(n/2)} }}$ 

The metallic mean for any given integer ${\displaystyle N}$  can be constructed geometrically in the following way. Define a right triangle with sides ${\displaystyle A}$  and ${\displaystyle B}$  having lengths of ${\displaystyle 1}$  and ${\displaystyle N/2}$ , respectively. The ${\displaystyle N}$ th metallic mean ${\displaystyle M}$  is simply the sum of the length of ${\displaystyle B}$  and the hypotenuse, ${\displaystyle H}$ .^[6]

For ${\displaystyle N=1}$ ,

${\displaystyle H={\sqrt {(N/2)^{2}+1^{2}}}={\sqrt {5/4}}=1.1180339...}$ 

and so

${\displaystyle M=B+H=1/2+1.1180339...=1.6180339...=}$  φ.

Setting ${\displaystyle N=2}$  yields the silver ratio.

${\displaystyle H={\sqrt {(2/2)^{2}+1^{2}}}={\sqrt {2}}=1.4142135...}$ 

Thus

${\displaystyle M=B+H=2/2+1.4142135...=2.4142135...}$ 

Likewise, the bronze ratio would be calculated with ${\displaystyle N=3}$  so

${\displaystyle H={\sqrt {(3/2)^{2}+1^{2}}}={\sqrt {13/4}}=1.8027756...}$ 

yields

${\displaystyle M=B+H=3/2+1.8027756...=3.3027756...}$ 

Non-integer arguments sometimes produce triangles with a mean that is itself an integer. Examples include N = 1.5, where

${\displaystyle H={\sqrt {(1.5/2)^{2}+1^{2}}}={\sqrt {1.5625}}=1.25}$ 

and

${\displaystyle M=B+H=1.5/2+1.25=2}$ 

Which is simply a scaled-down version of the 3-4-5 Pythagorean triangle.

• Constant
• Mean
• Ratio
• Plastic number

 j. OEIS: A084844 Denominators of the continued fraction n + 1/(n + 1/...) [n times]. 

• Stakhov, Alekseĭ Petrovich (2009). The Mathematics of Harmony: From Euclid to Contemporary Mathematics and Computer Science, p. 228, 231. World Scientific. ISBN 9789812775832.

• Cristina-Elena Hrețcanu and Mircea Crasmareanu (2013). "Metallic Structures on Riemannian Manifolds", Revista de la Unión Matemática Argentina.
• Rakočević, Miloje M. "Further Generalization of Golden Mean in Relation to Euler's 'Divine' Equation", Arxiv.org.