# Tag Info

## Hot answers tagged analysis

9

Big O notation does not give you the number of operations. It just tells you how fast it will grow with growing input. And this is what you observe. When you increased input c times, the total number of operations grows c^2. If you calculated (nearly) exact number of operations precisely you would get (n^2)/4. Of course you can calculate it with sums, but ...

4

Big-O notation doesn't care about constants because big-O notation only describes the long-term growth rate of functions, rather than their absolute magnitudes. Multiplying a function by a constant only influences its growth rate by a constant amount, so linear functions still grow linearly, logarithmic functions still grow logarithmically, exponential ...

3

If you try to write it down for several recursion cycles, you get this : 2*n^(1/2) [2*n^(1/4) (2*n^(1/8) . T(n^(1/16) + c log n) + c log n] + c log n If you try to count it, it would be (assymptoticaly) : 2^log n * n^(1/2 + 1/4 + 1/8 + ... + 1/log n) + 2^(log n) * n(1/2 + 1/4 + 1/8 + ... + 1/log n) * c * log n By sumation of series and thanks to that ...

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The inbuilt difflib might help http://docs.python.org/2/library/difflib.html But people seem to think this is tough Can difflib be used to make a plagiarism detection program?

2

Bear in mind that big-O is asymptotic notation. Constants (additive or multiplicative) have zero impact on it. So, the outer loop runs n times, and on the ith time, the inner loop runs i / 2 times. If it weren't for the / 2 part, it would be the sum of all numbers 1 .. n, which is the well known n * (n + 1) / 2. That expands to a * n^2 + b * n + c for a ...

2

Big-O notation only describes the growth rate of algorithms in terms of mathematical function, rather than the actual running time of algorithms on some machine. Mathematically, Let f(x) and g(x) be positive for x sufficiently large. We say that f(x) and g(x) grow at the same rate as x tends to infinity, if now let f(x)=x^2 and g(x)=x^2/2, then ...

1

You are completely right that constants matter. In comparing many different algorithms for the same problem, the O numbers without constants give you an overview of how they compare to each other. If you then have two algorithms in the same O class, you would compare them using the constants involved. But even for different O classes the constants are ...

1

Big O without constant is enough for algorithm analysis. First, the actual time does not only depend how many instructions but also the time for each instruction, which is closely connected to the platform where the code runs. It is more than theory analysis. So the constant is not necessary for most case. Second, Big O is mainly used to measure how the ...

1

Your understanding regarding time complexity is not appropriate.Time Complexity is not only the matter of 'sum' variable.'sum' only calculates how many times the inner loop iterates,but you also have to consider total number of outer loop iterations. now consider your program: for(int i = 1 ; i < n ; i++) for(int j = 0 ; j < i ; j +=2) ...

1

From your output it seems like: sum ~= (n^2)/4. This is obviously O(n^2) (actually you can replace the O with teta). You should recall the definition for Big-O notation. See http://en.wikipedia.org/wiki/Big_O_notation.

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You can changes the settings in the ElasticSearch.yml configuration file, at the very bottom of this file you can adjust the logging time to record all. index.search.slowlog.threshold.query.warn: 10s index.search.slowlog.threshold.query.info: 5s index.search.slowlog.threshold.query.debug: 2s index.search.slowlog.threshold.query.trace: 500ms ...

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Expected time complexity is ET(n) = O(nlogn) . Following is math proof derived by myself please tell if any error :- ET(n) = P(k=1)*(ET(1)+ET(n-1)) + P(k=2)*(ET(2)+ET(n-2)).......P(k=n-1)*(ET(n-1)+ET(1)) + c*n As the RNG is uniformly random P(k=x) = 1/n for all x hence ET(n) = 1/n*(ET(1)*2+ET(2)*2....ET(n-1)*2) + c*n ET(n) = 2/n*sum(ET(i)) + c*n i in ...

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Well you do need to define a function1 but you can reuse the existing name (and make the definition much leaner): table = function (..., useNA = 'ifany') base::table(..., useNA = useNA) This will make the new functionality available under the old name – but only in your code, so it’s “safe” (i.e. it doesn’t change packages’ use of table). We use ... to ...

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