Perfect digital invariant

Template:Short description In number theory, a perfect digital invariant (PDI) is a number in a given number base (${\displaystyle b}$) that is the sum of its own digits each raised to a given power (${\displaystyle p}$).^[1][2]

Let ${\displaystyle n}$ be a natural number. The perfect digital invariant function (also known as a happy function, from happy numbers) for base ${\displaystyle b>1}$ and power ${\displaystyle p>0}$ ${\displaystyle F_{p,b}:\mathbb{N}\to \mathbb{N}}$ is defined as:

${\displaystyle F_{p,b}(n)={\displaystyle \sum _{i=0}^{k-1}}{d}_i^p.}$

where ${\displaystyle k=\lfloor {\log }_{b}n\rfloor +1}$ is the number of digits in the number in base ${\displaystyle b}$, and

${\displaystyle d_i=\frac{nmod{b}^{i+1}-n{modb}^i}{b^i}}$

is the value of each digit of the number. A natural number ${\displaystyle n}$ is a perfect digital invariant if it is a fixed point for ${\displaystyle F_{p,b}}$, which occurs if ${\displaystyle F_{p,b}(n)=n}$. ${\displaystyle 0}$ and ${\displaystyle 1}$ are trivial perfect digital invariants for all ${\displaystyle b}$ and ${\displaystyle p}$, all other perfect digital invariants are nontrivial perfect digital invariants.

For example, the number 4150 in base ${\displaystyle b=10}$ is a perfect digital invariant with ${\displaystyle p=5}$, because ${\displaystyle 4150=4^5+1^5+5^5+0^5}$.

A natural number ${\displaystyle n}$ is a sociable digital invariant if it is a periodic point for ${\displaystyle F_{p,b}}$, where ${\displaystyle F_{p,b}^k(n)=n}$ for a positive integer ${\displaystyle k}$ (here ${\displaystyle F_{p,b}^k}$ is the ${\displaystyle k}$th iterate of ${\displaystyle F_{p,b}}$), and forms a cycle of period ${\displaystyle k}$. A perfect digital invariant is a sociable digital invariant with ${\displaystyle k=1}$, and a amicable digital invariant is a sociable digital invariant with ${\displaystyle k=2}$.

All natural numbers ${\displaystyle n}$ are preperiodic points for ${\displaystyle F_{p,b}}$, regardless of the base. This is because if ${\displaystyle k\ge p+2}$, ${\displaystyle n\ge b^{k-1}>b^{p}k}$, so any ${\displaystyle n}$ will satisfy ${\displaystyle n>F_{b,p}(n)}$ until ${\displaystyle n<b^{p+1}}$. There are a finite number of natural numbers less than ${\displaystyle b^{p+1}}$, so the number is guaranteed to reach a periodic point or a fixed point less than ${\displaystyle b^{p+1}}$, making it a preperiodic point.

Numbers in base ${\displaystyle b>p}$ lead to fixed or periodic points of numbers ${\displaystyle n\le (p-2{)}^p+p(b-1{)}^p}$.

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The number of iterations ${\displaystyle i}$ needed for ${\displaystyle F_{p,b}^i(n)}$ to reach a fixed point is the perfect digital invariant function's persistence of ${\displaystyle n}$, and undefined if it never reaches a fixed point.

${\displaystyle F_{1,b}}$ is the digit sum. The only perfect digital invariants are the single-digit numbers in base ${\displaystyle b}$, and there are no periodic points with prime period greater than 1.

${\displaystyle F_{p,2}}$ reduces to ${\displaystyle F_{1,2}}$, as for any power ${\displaystyle p}$, ${\displaystyle 0^p=0}$ and ${\displaystyle 1^p=1}$.

For every natural number ${\displaystyle k>1}$, if ${\displaystyle p<b}$, ${\displaystyle (b-1)\equiv 0modk}$ and ${\displaystyle (p-1)\equiv 0mod\varphi (k)}$, then for every natural number ${\displaystyle n}$, if ${\displaystyle n\equiv mmodk}$, then ${\displaystyle F_{p,b}(n)\equiv mmodk}$, where ${\displaystyle \varphi (k)}$ is Euler's totient function. Template:Math proof

No upper bound can be determined for the size of perfect digital invariants in a given base and arbitrary power, and it is not currently known whether or not the number of perfect digital invariants for an arbitrary base is finite or infinite.^[1]

By definition, any three-digit perfect digital invariant ${\displaystyle n=d_2{d}_1{d}_0}$ for ${\displaystyle F_{2,b}}$ with natural number digits ${\displaystyle 0\le d_0<b}$, ${\displaystyle 0\le d_1<b}$, ${\displaystyle 0\le d_2<b}$ has to satisfy the cubic Diophantine equation ${\displaystyle d_0^2+d_1^2+d_2^2=d_2{b}^2+d_{1}b+d_0}$. ${\displaystyle d_2}$ has to be equal to 0 or 1 for any ${\displaystyle b>2}$, because the maximum value ${\displaystyle n}$ can take is ${\displaystyle n=(2-1{)}^2+2(b-1{)}^2=1+2(b-1{)}^2<2b^2}$. As a result, there are actually two related quadratic Diophantine equations to solve:

${\displaystyle d_0^2+d_1^2=d_{1}b+d_0}$ when ${\displaystyle d_2=0}$, and

${\displaystyle d_0^2+d_1^2+1=b^2+d_{1}b+d_0}$ when ${\displaystyle d_2=1}$.

The two-digit natural number ${\displaystyle n=d_1{d}_0}$ is a perfect digital invariant in base

${\displaystyle b=d_1+\frac{d_0(d_0-1)}{d_1}.}$

This can be proven by taking the first case, where ${\displaystyle d_2=0}$, and solving for ${\displaystyle b}$. This means that for some values of ${\displaystyle d_0}$ and ${\displaystyle d_1}$, ${\displaystyle n}$ is not a perfect digital invariant in any base, as ${\displaystyle d_1}$ is not a divisor of ${\displaystyle d_0(d_0-1)}$. Moreover, ${\displaystyle d_0>1}$, because if ${\displaystyle d_0=0}$ or ${\displaystyle d_0=1}$, then ${\displaystyle b=d_1}$, which contradicts the earlier statement that ${\displaystyle 0\le d_1<b}$.

There are no three-digit perfect digital invariants for ${\displaystyle F_{2,b}}$, which can be proven by taking the second case, where ${\displaystyle d_2=1}$, and letting ${\displaystyle d_0=b-a_0}$ and ${\displaystyle d_1=b-a_1}$. Then the Diophantine equation for the three-digit perfect digital invariant becomes

${\displaystyle (b-a_0{)}^2+(b-a_1{)}^2+1=b^2+(b-a_1)b+(b-a_0)}$

${\displaystyle b^2-2a_{0}b+a_0^2+b^2-2a_{1}b+a_1^2+1=b^2+(b-a_1)b+(b-a_0)}$

${\displaystyle 2b^2-2(a_0+a_1)b+a_0^2+a_1^2+1=b^2+(b-a_1)b+(b-a_0)}$

${\displaystyle b^2+(b-2(a_0+a_1))b+a_0^2+a_1^2+1=b^2+(b-a_1)b+(b-a_0)}$

${\displaystyle 2(a_0+a_1)>a_1}$ for all values of ${\displaystyle 0<a_1\le b}$. Thus, there are no solutions to the Diophantine equation, and there are no three-digit perfect digital invariants for ${\displaystyle F_{2,b}}$.

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By definition, any four-digit perfect digital invariant ${\displaystyle n}$ for ${\displaystyle F_{3,b}}$ with natural number digits ${\displaystyle 0\le d_0<b}$, ${\displaystyle 0\le d_1<b}$, ${\displaystyle 0\le d_2<b}$, ${\displaystyle 0\le d_3<b}$ has to satisfy the quartic Diophantine equation ${\displaystyle d_0^3+d_1^3+d_2^3+d_3^3=d_3{b}^3+d_2{b}^2+d_{1}b+d_0}$. ${\displaystyle d_3}$ has to be equal to 0, 1, 2 for any ${\displaystyle b>3}$, because the maximum value ${\displaystyle n}$ can take is ${\displaystyle n=(3-2{)}^3+3(b-1{)}^3=1+3(b-1{)}^3<3b^3}$. As a result, there are actually three related cubic Diophantine equations to solve

${\displaystyle d_0^3+d_1^3+d_2^3=d_2{b}^2+d_{1}b+d_0}$ when ${\displaystyle d_3=0}$

${\displaystyle d_0^3+d_1^3+d_2^3+1=b^3+d_2{b}^2+d_{1}b+d_0}$ when ${\displaystyle d_3=1}$

${\displaystyle d_0^3+d_1^3+d_2^3+8=2b^3+d_2{b}^2+d_{1}b+d_0}$ when ${\displaystyle d_3=2}$

We take the first case, where ${\displaystyle d_3=0}$.

Let ${\displaystyle k}$ be a positive integer and the number base ${\displaystyle b=3k+1}$. Then:

• ${\displaystyle n_1=k{b}^2+(2k+1)b}$ is a perfect digital invariant for ${\displaystyle F_{3,b}}$ for all ${\displaystyle k}$.

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• ${\displaystyle n_2=k{b}^2+(2k+1)b+1}$ is a perfect digital invariant for ${\displaystyle F_{3,b}}$ for all ${\displaystyle k}$.

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• ${\displaystyle n_3=(k+1)b^2+(2k+1)}$ is a perfect digital invariant for ${\displaystyle F_{3,b}}$ for all ${\displaystyle k}$.

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Let ${\displaystyle k}$ be a positive integer and the number base ${\displaystyle b=3k+2}$. Then:

• ${\displaystyle n_1=k{b}^2+(2k+1)}$ is a perfect digital invariant for ${\displaystyle F_{3,b}}$ for all ${\displaystyle k}$.

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Let ${\displaystyle k}$ be a positive integer and the number base ${\displaystyle b=6k+4}$. Then:

• ${\displaystyle n_4=k{b}^2+(3k+2)b+(2k+1)}$ is a perfect digital invariant for ${\displaystyle F_{3,b}}$ for all ${\displaystyle k}$.

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All numbers are represented in base ${\displaystyle b}$.

Perfect digital invariants can be extended to the negative integers by use of a signed-digit representation to represent each integer.

In balanced ternary, the digits are 1, −1 and 0. This results in the following:

• With odd powers ${\displaystyle p\equiv 1mod2}$, ${\displaystyle F_{p,\text{bal}3}}$ reduces down to digit sum iteration, as ${\displaystyle (-1{)}^p=-1}$, ${\displaystyle 0^p=0}$ and ${\displaystyle 1^p=1}$.
• With even powers ${\displaystyle p\equiv 0mod2}$, ${\displaystyle F_{p,\text{bal}3}}$ indicates whether the number is even or odd, as the sum of each digit will indicate divisibility by 2 if and only if the sum of digits ends in 0. As ${\displaystyle 0^p=0}$ and ${\displaystyle (-1{)}^p=1^p=1}$, for every pair of digits 1 or −1, their sum is 0 and the sum of their squares is 2.

Template:Main A happy number ${\displaystyle n}$ for a given base ${\displaystyle b}$ and a given power ${\displaystyle p}$ is a preperiodic point for the perfect digital invariant function ${\displaystyle F_{p,b}}$ such that the ${\displaystyle m}$-th iteration of ${\displaystyle F_{p,b}}$ is equal to the trivial perfect digital invariant ${\displaystyle 1}$, and an unhappy number is one such that there exists no such ${\displaystyle m}$.

The example below implements the perfect digital invariant function described in the definition above to search for perfect digital invariants and cycles in Python. This can be used to find happy numbers.

def pdif(x: int, p: int, b: int) -> int:
    """Perfect digital invariant function."""
    total = 0
    while x > 0:
        total = total + pow(x % b, p)
        x = x // b
    return total

def pdif_cycle(x: int, p: int, b: int) -> list[int]:
    seen = []
    while x not in seen:
        seen.append(x)
        x = pdif(x, p, b)
    cycle = []
    while x not in cycle:
        cycle.append(x)
        x = pdif(x, p, b)
    return cycle

• Arithmetic dynamics
• Dudeney number
• Factorion
• Happy number
• Kaprekar's constant
• Kaprekar number
• Meertens number
• Narcissistic number
• Perfect digit-to-digit invariant
• Sum-product number

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• Digital Invariants

Template:Classes of natural numbers