- Published on
The Pigeonhole Principle and Leading Digits
- Authors

- Name
- Vu Hung
Problem Statement
For any real number , the fractional part of is denoted by and is defined as , where is the greatest integer less than or equal to . Note that .
For example, , .
(i) Show that for any positive integer , the ordinary decimal representation of begins with the digits (i.e., ) if and only if:
(ii) Let be an irrational number. Prove that for any two distinct integers and , the fractional parts and must be strictly distinct.
(iii) Let be a positive integer. By dividing the interval into equal subintervals, use the Pigeonhole Principle to prove that there exists a positive integer such that:
(iv) Given that is an irrational number, let By choosing an integer such that , or otherwise, deduce that there exists at least one positive integer such that begins with the digits .
Hints
- (i) Write in scientific notation: . If the number starts with 2025, what is bounded between? Take the base-10 logarithm.
- (ii) Proof by contradiction. Assume . Expand using the definition and isolate .
- (iii) Consider the fractional parts . Place these "pigeons" into the "holes" (subintervals).
- (iv) Think of the interval as a target of width . Part (iii) guarantees a "step size" strictly smaller than . Can consecutive steps jump over the target without landing inside it?
Solutions
- Part (i): begins with 2025 if and only if for some integer and . Taking logarithms yields . Since , we must have and . Substituting this into the inequality for yields the required result.
- Part (ii): Assume for integers . Then , which implies Since the numerator is an integer and the denominator is a non-zero integer, this forces to be rational, contradicting the premise. Thus, the fractional parts are distinct.
- Part (iii): Divide into equal intervals of width . By (ii), the values are strictly distinct. By the Pigeonhole Principle, two values must fall in the same interval. Thus, . Since lies in , it is exactly . Let (where ) to obtain .
- Part (iv): Choose such that . From (iii), let our step size be , noting . Consider the sequence of multiples . Because is strictly smaller than the target interval width , a multiple must eventually land inside . Therefore, satisfies the bounds. By letting , we satisfy the condition from (i).
Takeaways
- Kronecker's Theorem: This problem is a guided proof demonstrating that the orbit of an irrational rotation is dense. It guarantees that by doubling a number enough times, you can eventually generate a power of 2 that starts with any sequence of digits you desire.
- The Continuous Pigeonhole: By dividing a continuous number line into physical subintervals, we can force infinite irrational sequences to behave predictably.
