**Booth Id:**

MA007

**Category:**

Materials Science

**Year:**

2014

**Finalist Names:**

Hruskova, Aranka

**Abstract:**

Continued fractions have a long history behind them - their origin may be placed to the age of Euclid's algorithm for the greatest common divisor or even earlier. However, they experience a revival nowadays thanks to their applications in high-speed and high-accuracy computer arithmetic.
The continued fraction is usually defined as the expression a_0+b_0/(a_1+b_2/(a_2+b_3/(a_3+...))), where a_0 is an integer, b_i=1, and other variables are natural numbers. Every real number x can be written in the form of continued fraction; x's fraction is often simplified as x=[a_1,a_2,a_3,...]. According to Lagrange's theorem, an irrational number has a periodic continued fraction if and only if the number is a root of a quadratic equation with integer coefficients (we call such a root quadratic irrational). The goal of my project was to describe continued fractions of N^1/2, where N is a natural number. I defined N as N=n^2+j where j is from the set {1,2,...,2n}, and using a help of Wolfram Mathematica I created a table of period lengths of continued fractions of particular N^1/2-s. I studied the data and tried to observe any laws which I could prove. I described all continued fractions of N^1/2 with period lengths 1, 2, and 3 and many fractions with different period lengths. I also discovered a connection between continued fractions and Fibonacci numbers and made several not-yet-proved hypotheses.

**Awards Won:**

Second Award of $2,000