This is my question and I've managed to bring out an answer for part a, but for part b I'm not really confident about my answer of part b.

In a recent court case, a judge cited a city for contempt and ordered a fine of $2 for the first day. Each subsequent day, until the city followed the judge’s order, the fine was squared (i.e., the fine progressed as follows: $2, $4, $16, $256, $65,536,...). a. What would be the fine on day N? b. How many days would it take for the fine to reach D dollars (a Big-Oh answer will do)?

Ans a : 2^(2^n-1)

For answer b, I made the following program to find the big Oh.

for (int i = 0; i < n - 1; i++) {
    result = 2 * result;
printf("%d\t", result);

for (int j = 0; j < result; j++) {
    res = 2 * res ;
printf("%d\n", res);

I have calculated the big Oh of the first loop to be Sumation of n And since the second loop runs 2^n-1 times the first loop, its big Oh is 2^n and adding them both they become (2^n) + n


According to my algorithm my answer is O(N)

int days=5;
int fine = 2;
for(int i=0; i<days-1; i++)
   fine =  fine * fine;

cout << fine;

The first loop runs n-1 times, the second runs 2^(n-1) times. The time-complexity is the sum of these so (n-1) + 2^(n-1) = O(2^n + n) = O(2^n).

The question doesn't seem to be asking for the time-complexity though. It's asking how many days would pass before the fine reaches D dollars. This is the inverse of the answer to a): O(log log D) ($65536 is reached after log(log(65536)) + 1 days, for example).


You don't really need any software to answer these questions. Big O is a math term that happens to be used in software development.

Let's look at the progression:

2     = 2^1  = 2^(2^0)
4     = 2^2  = 2^(2^1)
16    = 2^4  = 2^(2^2)
256   = 2^8  = 2^(2^3)
65536 = 2^16 = 2^(2^4)

Answer to question a.

The penalty on day n would be 2^(2^(n-1)).

You could program it like this:

pow(2, pow(2, n-1));

Answer to question b.

x = log2 (log2 D) + 1

Or without the "+ 1" if we're not to count the first day.
This will return a positive real number, so you may want to ceil it depending on the requirements.

Now, in big O notation, it would be O(log(log)), which describes how the value grows. What that means is that when the input (D in this case) is multiplied by n, the value of the function will increase by at most log(log n) times.

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