Perfect digit-to-digit invariant

Let ${\displaystyle n}$  be a natural number which can be written in base ${\displaystyle b}$  as the k-digit number ${\displaystyle d_{k-1}d_{k-2}...d_{1}d_{0}}$  where each digit ${\displaystyle d_{i}}$  is between ${\displaystyle 0}$  and ${\displaystyle b-1}$  inclusive, and ${\displaystyle n=\sum _{i=0}^{k-1}d_{i}b^{i}}$ . We define the function ${\displaystyle F_{b}:\mathbb {N} \rightarrow \mathbb {N} }$  as ${\displaystyle F_{b}(n)=\sum _{i=0}^{k-1}{d_{i}}^{d_{i}}}$ . (As 0⁰ is usually undefined, there are typically two conventions used, one where it is taken to be equal to one, and another where it is taken to be equal to zero.^[5][6]) A natural number ${\displaystyle n}$  is defined to be a perfect digit-to-digit invariant in base b if ${\displaystyle F_{b}(n)=n}$ . For example, the number 3435 is a perfect digit-to-digit invariant in base 10 because ${\displaystyle 3^{3}+4^{4}+3^{3}+5^{5}=27+256+27+3125=3435}$ .

${\displaystyle F_{b}(1)=1}$  for all ${\displaystyle b}$ , and thus 1 is a trivial perfect digit-to-digit invariant in all bases, and all other perfect digit-to-digit invariants are nontrivial. For the second convention where ${\displaystyle 0^{0}=0}$ , both ${\displaystyle 0}$  and ${\displaystyle 1}$  are trivial perfect digit-to-digit invariants.

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

All natural numbers ${\displaystyle n}$  are preperiodic points for ${\displaystyle F_{b}}$ , regardless of the base. This is because all natural numbers of base ${\displaystyle b}$  with ${\displaystyle k}$  digits satisfy ${\displaystyle b^{k-1}\leq n\leq (k){(b-1)}^{b-1}}$ . However, when ${\displaystyle k\geq b+1}$ , then ${\displaystyle b^{k-1}>(k){(b-1)}^{b-1}}$ , so any ${\displaystyle n}$  will satisfy ${\displaystyle n>F_{b}(n)}$  until ${\displaystyle n<b^{b+1}}$ . There are a finite number of natural numbers less than ${\displaystyle b^{b+1}}$ , so the number is guaranteed to reach a periodic point or a fixed point less than ${\displaystyle b^{b+1}}$ , making it a preperiodic point. This means also that there are a finite number of perfect digit-to-digit invariant and cycles for any given base ${\displaystyle b}$ .

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

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

The following program in Python determines whether an integer number is a Munchausen Number / Perfect Digit to Digit Invariant or not, following the convention ${\displaystyle 0^{0}=1}$ .

num = int(input("Enter number:"))
temp = num
s = 0.0
while num > 0:
     digit = num % 10
     num //= 10
     s+= pow(digit, digit)
     
if s == temp:
    print("Munchausen Number")
else:
    print("Not Munchausen Number")

The examples below implement the perfect digit-to-digit invariant function described in the definition above to search for perfect digit-to-digit invariants and cycles in Python for the two conventions.

def pddif(x: int, b: int) -> int:
    total = 0
    while x > 0:
        total = total + pow(x % b, x % b)
        x = x // b
    return total

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

def pddif(x: int, b: int) -> int:
    total = 0
    while x > 0:
        if x % b > 0:
            total = total + pow(x % b, x % b)
        x = x // b
    return total

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

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

• Parker, Matt. "3435". Numberphile. Brady Haran. Archived from the original on 2017-04-13. Retrieved 2013-04-01.