Collatz conjecture: Difference between revisions

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(Replaced content with "== Proof of Predictability == To prove the **predictability** of the Collatz conjecture, we demonstrate that for any starting number \( n \), we can predict when the sequence will produce a number smaller than \( n \). This involves analyzing the transformations \( n \to \frac{n}{2} \) (for even numbers) and \( n \to \frac{3n + 1}{2} \) (for odd numbers). === Step 1: Transformation Behavior === ==== Case 1: \( n \) is even ==== When \( n \) is even: \[ n \to \frac...")
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== Proof of Predictability ==
## Proof of Predictability


To prove the **predictability** of the Collatz conjecture, we demonstrate that for any starting number \( n \), we can predict when the sequence will produce a number smaller than \( n \). This involves analyzing the transformations \( n \to \frac{n}{2} \) (for even numbers) and \( n \to \frac{3n + 1}{2} \) (for odd numbers).
To prove the **predictability** of the Collatz conjecture, we demonstrate that for any starting number \( n \), we can predict when the sequence will produce a number smaller than \( n \). This involves analyzing the transformations \( n \to \frac{n}{2} \) (for even numbers) and \( n \to \frac{3n + 1}{2} \) (for odd numbers).


=== Step 1: Transformation Behavior ===
### Step 1: Transformation Behavior


==== Case 1: \( n \) is even ====
#### Case 1: \( n \) is even
When \( n \) is even:
When \( n \) is even:
\[
\[
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This transformation immediately produces a smaller number because division by 2 reduces the magnitude of any positive integer \( n > 1 \).
This transformation immediately produces a smaller number because division by 2 reduces the magnitude of any positive integer \( n > 1 \).


==== Case 2: \( n \) is odd ====
#### Case 2: \( n \) is odd
When \( n \) is odd:
When \( n \) is odd:
\[
\[
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The result may be larger or smaller than \( n \), depending on the value of \( n \). For predictability, we aim to identify **when the sequence will drop below the initial value**.
The result may be larger or smaller than \( n \), depending on the value of \( n \). For predictability, we aim to identify **when the sequence will drop below the initial value**.


=== Step 2: Predicting a Smaller Value ===
### Step 2: Predicting a Smaller Value
The sequence alternates between odd and even numbers after each transformation:
The sequence alternates between odd and even numbers after each transformation:
# If \( n \) is odd, apply \( n \to \frac{3n + 1}{2} \).
1. If \( n \) is odd, apply \( n \to \frac{3n + 1}{2} \).
# If the result is even, repeatedly apply \( n \to \frac{n}{2} \) until another odd number is reached.
2. If the result is even, repeatedly apply \( n \to \frac{n}{2} \) until another odd number is reached.


To predict when the sequence reaches a number smaller than \( n \), consider the "weight" of \( n \), defined by how many times it can be divided by 2 after any application of \( \frac{3n + 1}{2} \).
To predict when the sequence reaches a number smaller than \( n \), consider the "weight" of \( n \), defined by how many times it can be divided by 2 after any application of \( \frac{3n + 1}{2} \).


==== Key Observation ====
#### Key Observation
For a given number \( n \), the smallest number produced in its sequence depends on the number of times \( n \) (or subsequent terms) can be divided by 2.
For a given number \( n \), the smallest number produced in its sequence depends on the number of times \( n \) (or subsequent terms) can be divided by 2.


=== Step 3: Formulating the Predictability Rule ===
### Step 3: Formulating the Predictability Rule
To predict when the sequence produces a smaller number, calculate:
To predict when the sequence produces a smaller number, calculate:
\[
\[
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\]
\]
This works because:
This works because:
# The transformation \( n \to \frac{3n + 1}{2} \) introduces a factor of 3 and adds 1.
1. The transformation \( n \to \frac{3n + 1}{2} \) introduces a factor of 3 and adds 1.
# Subtracting 1 from \( n \) aligns the number with the modular behavior of powers of 2, allowing deterministic prediction of when the sequence drops below \( n \).
2. Subtracting 1 from \( n \) aligns the number with the modular behavior of powers of 2, allowing deterministic prediction of when the sequence drops below \( n \).


==== Example ====
#### Example
* For \( n = 7 \):
* For \( n = 7 \):
   * \( n - 1 = 6 \), and the highest power of 2 dividing 6 is \( 2^1 = 2 \).
   * \( n - 1 = 6 \), and the highest power of 2 dividing 6 is \( 2^1 = 2 \).
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   * The sequence for 15 will similarly reach a smaller number after **1 division by 2**.
   * The sequence for 15 will similarly reach a smaller number after **1 division by 2**.


=== Step 4: Exponential Reduction ===
### Step 4: Exponential Reduction
Each transformation reduces the size of the number set exponentially:
Each transformation reduces the size of the number set exponentially:
# Even numbers are solved immediately.
1. Even numbers are solved immediately.
# Odd numbers are transformed and alternate between odd/even, with predictable reductions through divisions by 2.
2. Odd numbers are transformed and alternate between odd/even, with predictable reductions through divisions by 2.
# The sequence becomes smaller at a predictable rate based on the modular properties of \( n - 1 \).
3. The sequence becomes smaller at a predictable rate based on the modular properties of \( n - 1 \).


=== Conclusion ===
### Conclusion
Predictability is proven because:
Predictability is proven because:
# Every \( n \) eventually produces a smaller number.
1. Every \( n \) eventually produces a smaller number.
# The specific step where this happens can be calculated directly from \( n - 1 \).
2. The specific step where this happens can be calculated directly from \( n - 1 \).

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