Mathematical Meanderings

Saturday, 7 February 2026

A Revision

In my previous post, I made a modification to the following algorithm:

Suppose we take any positive integer $n \gt 1$

if prime, double it and add 1: $n \rightarrow 2n+1$
if composite, determine its number of divisors $d$

if $ n \pmod d \equiv 0$ then $n \rightarrow \dfrac{n}{d} $
if $ n \pmod d \not\equiv 0 $ then $n \rightarrow n \times d$

Keep repeating this process until a loop is reached or call a stop after a fixed number of iterations.

The modification I made prevented the numbers generated from becoming too large too quickly. Instead of doubling a prime and adding 1, I decided to do this only if the number was a $4k+1$ prime. If it was a $4k+3$, I subtracted 1 and divided by 2. The new algorithm looks like this:

if a $4k+1$ prime, double it and add 1: $n \rightarrow 2n+1$
if a $4k+3$ prime, subtract 1 and divide by 2: $n \rightarrow (n-1)/2$
if composite, determine its number of divisors $d$

if $ n \pmod d \equiv 0$ then $n \rightarrow \dfrac{n}{d} $
if $ n \pmod d \not\equiv 0 $ then $n \rightarrow n \times d$

Here is an example using 28069 (permalink):

--- Loop detected at value 149708 ---
Divisors to Sequence:
28069, 56139, 224556, 18713, 37427, 149708, 1796496, 71859840, 561405, 8982480, 112281, 898248, 28743936, 2069563392, 10778976, 149708
------------------------------
Sequence Length: 16
Highest Value: 2069563392

This method of dealing with primes is also better suited to the sequences I mentioned earlier in my two posts:

Here are the two new algorithms.

Suppose we take any positive integer $n \gt 1$ and apply the following rules to it:

if a $4k+1$ prime, double it and add 1: $n \rightarrow 2n+1$
if a $4k+3$ prime, subtract 1 and divide by 2: $n \rightarrow (n-1)/2$
if composite, determine its number of factors $f$ counted $ \textbf{with multiplicity}$

if $ n \pmod f \equiv 0$ then $n \rightarrow \dfrac{n}{f} $
if $ n \pmod f \not\equiv 0 $ then $n \rightarrow n \times f$

Keep repeating this process until a loop is reached or call a stop after a fixed number of iterations.

Here is an example using 28069 (permalink):

--- Loop detected at value 37427 ---
Number of factors to sequence with multiplicity:
28069, 56139, 112278, 37426, 18713, 37427, 74854, 224562, 898248, 149708, 37427
--------------------
Sequence Length: 11

Highest Value: 898248

Suppose we take any positive integer $n \gt 1$ and apply the following rules to it:

if a $4k+1$ prime, double it and add 1: $n \rightarrow 2n+1$
if a $4k+3$ prime, subtract 1 and divide by 2: $n \rightarrow (n-1)/2$
if composite, determine its number of factors $f$ counted $ \textbf{without multiplicity}$

if $ n \pmod f \equiv 0$ then $n \rightarrow \dfrac{n}{f} $
if $ n \pmod f \not\equiv 0 $ then $n \rightarrow n \times f$

Keep repeating this process until a loop is reached or call a stop after a fixed number of iterations.

Here is an example using 28069 (permalink):

--- Loop detected at value 224562 ---
28069, 56139, 112278, 37426, 18713, 37427, 74854, 224562, 898248, 224562
--------------------
Sequence Length: 10
Highest Value: 898248

Friday, 6 February 2026

A Correction

After creating my post Number's Divisors to Sequence Algorithm, I was feeling satisfied. I'd gotten Gemini to create a neat little table for me. It showed the record lengths reached by numbers under the algorithm in the range up to one million but suffered from the fact that it was simply wrong. Here is the original table:

Number     | Length     | Status
-----------------------------------
2          | 5          | New Record!     
3          | 8          | New Record!     
6          | 10         | New Record!     
11         | 21         | New Record!     
22         | 23         | New Record!     
44         | 25         | New Record!     
50         | 28         | New Record!     
99         | 32         | New Record!     
125        | 33         | New Record!     
206        | 34         | New Record!     
350        | 37         | New Record!     
463        | 44         | New Record!     
487        | 46         | New Record!     
974        | 48         | New Record!     
1375       | 51         | New Record!     
1573       | 52         | New Record!     
1625       | 60         | New Record!     
5200       | 62         | New Record!     
14157      | 63         | New Record!     
16879      | 64         | New Record!     
18747      | 67         | New Record!     
39325      | 70         | New Record!     
89237      | 71         | New Record!     
151911     | 75         | New Record!     
563553     | 77         | New Record!     
803133     | 82         | New Record!

Fortunately I spotted the problem when looking at the trajectory of the number associated with my diurnal age: 28068. It showed a length of 201, far in excess of the 82 associated with 803133. Furthermore, the algorithm only counted up to 201 and so the sequence was longer than that.

Naturally I confronted Gemini about the problem and here was its response:

The Reason for the DiscrepancyThe sequence for 28068 exhibits a behavior known as a Cunningham Chain.Your rule if is_prime: number = number * 2 + 1 matches the definition of a Cunningham Chain (where $p \to 2p+1$).If the sequence hits a "vein" of consecutive primes (e.g., a chain of 40 primes), the number grows by a factor of $2^{40}$ (approx. 1 trillion). My previous Python code had a safety brake: if number > $10^12$: break. 28068 likely skyrockets past one trillion ($10^{12}$) very quickly. My code hit this safety limit and stopped counting, reporting a truncated (incorrect) length.

Gemini proposed modifications to the code but these overtaxed the Jupyter notebook and it got stuck at a point shown in Figure 1.

Figure 1

Eventually I decided to get Gemini to write the code for just a single number as input and not a range. Even this proved too much for the Jupyter notebook. I don't know whether the sequence for 28068 goes on forever or not but I do know that the original algorithm that Gemini provided me with was flawed. It was only by chance that I found this out so caution is advised in accepting anything Gemini offers up. I'm commented in the past on its coding limitations.

The failure of the algorithm to reach completion is attributed to Cunningham chains so I'd thought I'd better look back at that topic. It turns out that the longest known Cunningham chain of the first kind ($2p+1$ is 17 primes long so why does Gemini mention chains of 40 primes when none are known? Nonetheless, it's likely that the $2p+1$ rule that I'm applying to prime numbers does lead quickly to very large number. My choice of this rule was quite arbitrary. Given that $4k+1$ and $4k-1$ primes are pretty much in equal abundance, I could apply an alternative rule such as the following to a prime $p$:

if $p \pmod 4 \equiv 1$ then $p \rightarrow 2 \times p +1 $
if $p \pmod 4 \equiv 3$ then $p \rightarrow (p -1 )/2 $

This should keep the progressive numbers from growing too large. I should do this with the factors as well (see earlier posts Number's Factors to Sequence Algorithm 1 and Number's Factors to Sequence Algorithm 2). Figure 2 shows the record breaking numbers under these new rules (up to one million).

Figure 2: permalink

In summary, the record breaking numbers are 1, 2, 4, 13, 17, 34, 50, 98, 294, 650, 722, 2166, 4751, 5313, 9502, 11979, 19773, 46137, 125229, 257049, 385573, 714025.

I also got Gemini to write the code for the input of a single number and the trajectory of the number as output. Let's use 28068 as an example. Figure 2 shows the output.

Figure 3: permalink

Thursday, 5 February 2026

Why Is 313131 An Interesting Number?

Recently a friend of mine who was staying at a hotel revealed that the six digit security code for the room was 313131. This looked like an easy code to crack and I was reminded of a post that I'd made recently titled Passcodes and Repeated Digits in November of 2025. Figure 1 shows the probabilities for the number of distinct digits chosen:

Figure 1

So the code 313131 is indeed easy to crack, requiring only a maximum of 62 attempts or 31 attempts on average. However, what was of most interest to me regarding 313131 was its prime factorisation:$$ 313131=3 \times 7 \times 13 \times 31 \times 37$$If we rearrange the order of multiplication we get the following:$$ 313131=7 \times 3 \times 13 \times 31 \times 37$$Concatenating these digits we get the number $73133137$ which is palindromic.

Naturally, I wondered how many other numbers share this property and so I set Gemini to investigate this with the following prompt:

Write a program in Python, tailored for insertion into SageMathCell or a Jupyter notebook, that identifies all composite numbers from 4 up to a user chosen upper limit with the property that the prime factors, when arranged in a suitable order and then concatenated, produce a palindromic number. The default upper limit can be set to 40000. An example of such a number would be 313131 = 3 x 7 x 13 x 31 x 37 that can written as 7 x 3 x 13 x 31 x 37 to produce the palindromic number 73133137 when concatenated. The output of the program should be a table showing number and factorisation followed by a comma separated list of the qualifying numbers.

Naturally this a processor intensive process and my Jupyter notebook struggled mightily to generate the list of suitable numbers. After some time, I decided to restrict the range to between 28000 and 29000 and after further modifications by Gemini, I was able to achieve the following list of numbers:

28072, 28125, 28194, 28224, 28242, 28273, 28308, 28322, 28332, 28416, 28431, 28448, 28585, 28589, 28593, 28601, 28602, 28609, 28620, 28672, 28685, 28692, 28750, 28800, 28812, 28847, 28951

Figure 2 shows the details:

Figure 2

I've incorporated this algorithm into my daily search program that has become somewhat impressive if I do say so myself. See Figure 3 for the results of 28067, my diurnal age today.



Figure 3

The output is generated by the same program but I've just restricted the range to my daily number, rather lazy but it does the job. Remember the prime factorisation takes multiplicity into account. For completeness I'll include the Python code:

import sys

def get_prime_factors(n):
    """Returns a list of prime factors of n."""
    factors = []
    d = 2
    temp = n
    while d * d <= temp:
        while temp % d == 0:
            factors.append(d)
            temp //= d
        d += 1
    if temp > 1:
        factors.append(temp)
    return factors

def is_palindrome(s):
    """Checks if a string is a palindrome."""
    return s == s[::-1]

def distinct_permutations(iterable):
    """
    Yields unique permutations of items in iterable.
    This handles repeated elements efficiently (e.g., [2, 2, 3])
    without generating all n! redundant combinations.
    """
    # Sort the list to start with the lexicographically first permutation
    s = sorted(iterable)
    yield tuple(s)
    
    n = len(s)
    while True:
        # 1. Find the largest index i such that s[i] < s[i+1]
        i = n - 2
        while i >= 0 and s[i] >= s[i+1]:
            i -= 1
        
        if i == -1:
            return # All permutations generated
        
        # 2. Find the largest index j such that s[i] < s[j]
        j = n - 1
        while s[j] <= s[i]:
            j -= 1
        
        # 3. Swap s[i] and s[j]
        s[i], s[j] = s[j], s[i]
        
        # 4. Reverse the sequence from s[i+1] up to the end
        s[i+1:] = s[i+1:][::-1]
        
        yield tuple(s)

def find_palindromic_composites(start_n, end_n):
    results = []
    actual_start = max(4, start_n)

    for n in range(actual_start, end_n + 1):
        factors = get_prime_factors(n)
        
        # Skip primes
        if len(factors) < 2:
            continue
            
        found_property = False
        winning_perm = None
        winning_concat = None
        
        # Use the optimized generator instead of itertools.permutations
        for p in distinct_permutations(factors):
            concat_str = "".join(map(str, p))
            
            if is_palindrome(concat_str):
                found_property = True
                winning_perm = p
                winning_concat = concat_str
                break 
        
        if found_property:
            fact_str = " x ".join(map(str, winning_perm))
            results.append((n, fact_str, winning_concat))

    return results

# --- Configuration ---
LOWER_BOUND = 28000
UPPER_BOUND = 29000

# --- Main Execution ---
print(f"Searching for composite numbers between {LOWER_BOUND} and {UPPER_BOUND}...")
print("-" * 80)
print(f"{'Number':<8} | {'Valid Factor Ordering':<35} | {'Resulting Palindrome'}")
print("-" * 80)

qualifying_numbers = find_palindromic_composites(LOWER_BOUND, UPPER_BOUND)

if not qualifying_numbers:
    print(f"No qualifying numbers found in the range {LOWER_BOUND} to {UPPER_BOUND}.")
else:
    for num, factor_str, pal_str in qualifying_numbers:
        print(f"{num:<8} | {factor_str:<35} | {pal_str}")

    print("-" * 80)
    print("\nComma separated list of qualifying numbers:")
    print(", ".join(str(r[0]) for r in qualifying_numbers))

Tuesday, 3 February 2026

Why Is 29 Special?

This little puzzle appeared in Puzzle A Day.

What is the only number that, when written in typed letters as all capitals, is made up of exactly the same number of straight-line segments as the value of the number itself? For example, FIVE uses 10 straight lines, so it cannot be the answer. (Ignore any hyphens in the spelled-out number.)

I asked Gemini to create a table for the number of straight line segments in each letter of the English alphabet and then solve the puzzle.

Based on a standard analysis of the straight line segments in the uppercase English alphabet (using a typical sans-serif block font), here is the breakdown.

Table of Straight Line Segments per Letter

Letter	Segments	Shape Breakdown
A	3	Two diagonal, one horizontal
B	1	One vertical (curves do not count)
C	0	All curved
D	1	One vertical
E	4	One vertical, three horizontal
F	3	One vertical, two horizontal
G	1	One short horizontal shelf
H	3	Two vertical, one horizontal
I	1	One vertical
J	0	Typically a hook (though some fonts use 1 vertical)
K	3	One vertical, two diagonal
L	2	One vertical, one horizontal
M	4	Two vertical, two diagonal
N	3	Two vertical, one diagonal
O	0	All curved
P	1	One vertical
Q	1	One short diagonal tail
R	2	One vertical, one diagonal leg
S	0	All curved
T	2	One vertical, one horizontal
U	0	Typically a curve (block versions may have 2 vertical)
V	2	Two diagonal
W	4	Four diagonal
X	2	Two diagonal
Y	3	Two diagonal, one vertical (or three meeting at center)
Z	3	Two horizontal, one diagonal

The Numbers That Match

Using the values from the table above, we can deduce which integers (when written as English words) have a value equal to their total number of straight line segments.

There are exactly two integers that satisfy this condition:

1. SIXTEEN

S (0) + I (1) + X (2) + T (2) + E (4) + E (4) + N (3)
Calculation: $0 + 1 + 2 + 2 + 4 + 4 + 3 = \mathbf{16}$
Result: The word "SIXTEEN" is made of 16 straight lines, which equals its value.

2. TWENTY NINE

TWENTY: T (2) + W (4) + E (4) + N (3) + T (2) + Y (3) = 18
NINE: N (3) + I (1) + N (3) + E (4) = 11
Calculation: $18 + 11 = \mathbf{29}$
Result: The words "TWENTY NINE" are made of 29 straight lines, which equals its value.

**************************

In the answer supplied to the puzzle, only 29 is listed and not 16 as well. Why I'm not sure but the letters of 29 are made up ONLY of straight line segments whereas 16 contains the curved letter S.