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I am asked to determine use the time and space complexities of simple algorithms. The problem is that I don't fully understand where the numbers come from. From example we were provided it counts addition, subtraction, division, and multiplication as primitive operations.

Here I am posting pseudo code of my algorithm which calculates standard deviation by using formula we were provided.

I see 2 * (n - 1) addition symbols, 1 division symbol, 2 multiplication symbol and 1 subtraction symbol.

What else I must count here for time complexity? And what to do with space complexity?

// X is passed array, and N is number of elements in array.
Algorithm calculateStandardDeviation(X, N)
    private double arraySum;
    private double arrayMean;
    private double xi2;
    private double standardDeviation;

    foreach (arrayValue in X)
        arraySum = arraySum + arrayValue;

    arrayMean = sum / N;

    foreach (arrayValue in X)
        xi2 = xi2 + Math.Pow(arrayValue, 2);

    standardDeviation = Math. Sqrt(((1/N) * () * xi2) - Math.Pow(arrayMean, 2));

    return standardDeviation;
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Look at the for loops, and especially the depth to which they are nested. –  David Robinson Sep 18 '12 at 19:14

1 Answer 1

up vote 2 down vote accepted

Algorithmic Complexity can, ironically, be as general or complex as you want. If you are working towards a big-oh O(...) notation complexity - as is the norm in computer science - @david robinson is correct with respect to your current situation.

A for loop generally adds a dimension of N time complexity - where N is the number of runs your loop contains. Everything else you do runs in O(1) "constant" time (does NOT mean takes the same amount of physical time as another O(1) time op). Therefore, your time complexity is the linear addition of all your operations or O(N + N + 1 + 1+...) = O(2N). This, i'm sure you learned in class, reduces to O(N). Time complexity.

Now for space complexity - same thing. Does anything grow as your input sizes grow? That would be a yes - your array grows as you add more elements to your array. Therefore it, too, grows as O(N). You have other constant space factors, but we're dropping that for big-oh, giving you

linear - O(N) - in time and space complexity.

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But would you say that as X grows twice as large, the space taken up by the sum of its elements grows by the same factor? I don't think that's right. –  Blender Sep 18 '12 at 19:26
No I would not, that's actually peaked at 2/4/8 bytes depending on the size you store it in. I only glanced at his code, did I miss something? –  im so confused Sep 18 '12 at 19:28
ok reading a little more carefully, still sticking with that - the array size grows as per your input growth. All the other factors remain relatively constant in size. –  im so confused Sep 18 '12 at 19:30
For some reason I thought that the space complexity of the xi2 was nonlinear due to the arrayValue^2 term being added each iteration. I tested it in Python for X ranging from [0] to [0...10000] and the space complexity seems to be linear: i.imgur.com/vxo2v.png –  Blender Sep 18 '12 at 19:35
Ah, no, unfortunately xi2 is stored in a "double" and is thus capped by the OS in terms of space. Your empirical results show excellent detective work though, would you like to edit my answer and add them in? –  im so confused Sep 18 '12 at 19:37

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