Due Wednesday, October 23rd, 2024

  1. Find the square root(s), if any, of $3$ modulo $11$ using the algorithm from the end of class.  Now draw the dynamical portrait of powers of $3$ modulo $11$.  Label each vertex as $3^x = y$ for whatever x and y, so each vertex can be interpreted as its value mod $p$ and its power of $3$.  Can you use this diagram to explain why the method works?
  2. Write a small for loop in sage that runs the Blum-Blum-Shub pseudo-random number generator.
  3. Invent a way to check that the output “looks random”.  Do you know a good statistical test?  Or could you graph it somehow?  If you discover some type of non-random-ish behaviour, it could lead to a way to factor integers!
  4. Explain how, if you can factor $n$, you could find square roots modulo $n = pq$ where $p,q$ are primes congruent to $3$ modulo $4$.  This is basically just recalling something we did in class.
  5. Explain how, if you can find square roots modulo $n$, this allows you to factor $n$.  (Find square roots means find all square roots.)  This is basically just recalling something we did in class.  This and the previous exercise show that factoring $n$ is considered equivalent to finding square roots modulo $n$.