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I am not completely sure about the following table

alt text

The table provides the size of problem that can be solved in the time limit given in the left-hand column when the algorithmic complexity is of the given size.

I am interested in the deduction of the table.

The table suggests me that

  • O(n) = 10M in a second (This seems to be the power of current computers)
  • n is the number of items to process # Thanks to Guffa!

I am not sure how the values in the column of O(n * log(n)) have been deduced.

  1. How can you deduce the value 0.5M for O(n * log(n)) or 3000 for O(n^2)?
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You say you are a mathematics student and then you start with assuming that n=1 when you think about something with log(n) in it? (hint log(1)=0, so maybe not the best value to start calculations about O(n*log(n)).) And have you heard about that O(...) notation before? Probably there was mentioned that this is saying something about large n. "1" isn't particularly large. – sth Jun 28 '09 at 11:31
@sth: You are right. My confusion was that it did not make sense for me if n=1 because then we get 0 > 0.5M, which is ridiculous. I clearly need to clarify my question. – Masi Jun 28 '09 at 11:34
It seems that the author of the table uses some standard value for n, since otherwise we cannot deduce the values in the table. – Masi Jun 28 '09 at 11:38
up vote 1 down vote accepted

I think that this table gives simply some very approximate illustration how big n can be for different kind of complexities when you have fixed time (1 second, 1 minute, 1 hour, 1 day or 1 year) at your disposal.

For example O(n^3):

 1 second: 200^3 = 8 000 000 (roughly 10 million, given in O(n) column)
 1 minute: 850^3 = 614 125 000 (roughly 600 million, given in O(n) column))
 1 hour: 3000^3 = 27 000 000 000 (somewhat roughly 35 billion, given in O(n) column)

As you can see, the number are very rough approximations. It seems that author has wanted to use nice round numbers to illustrate his point.

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@Juha: Thank you very much for your answer! -- The math makes sense now for me :) – Masi Jun 28 '09 at 12:04
Your answer raised a new question: If n = 200 deduced from O(n^3). Why is the value in O(n) then 10M, not 200? – Masi Jun 28 '09 at 12:43
It's not n that is 200, the values in the table is not n. The n value is for example how many items you have in a collection. The value in the table is for example how many items you can read from the collection per time unit, depending on how efficient the algorithm is at reading items. It's pretty hard to make anything out of the table though, as the O notation doesn't measure efficiency itself but rather changes in efficiency... – Guffa Jun 28 '09 at 15:22
@Guffa: So the key point is that O -notation measures changes in the rate, not the actual rate, similarly as we measure enthalpy by changes in Chemistry. – Masi Jun 28 '09 at 19:51
@Guffa: It seems that the benefit of O notation is when there is a change in the algorithm such that we can estimate the best algorithm. --- Can we measure the code's effectiveness by only pencil and paper, by comparing the rate of an algorithm to a base value? – Masi Jun 28 '09 at 20:08

No, n is not the number of seconds, it's the number of items to process.

O(n) means that the time to process the items is linear to the number of items.

O(n²) means that the time to proess the items is relative to the square of the number of items. If you double the number of items, the processing time will be four times longer.

See: Big O notation

The table assumes that there is a fixed amount of work per item, although the big O notation only specifies how an algorithm reacts to a change in number of items, it doesn't tell you anything about how much work there is per item.

The values along the x axis of the table are just approximations based on the assumption that the work per item is the same. For example the value 3000 for O(n²) is rounded from the square root of 10 millions, which is ~3162.28. The cubic root of 10 millions is not 200, it's ~215.44.

In a real situatuon, two algorithms rarely do the same amount of work per item. An algorithm with O(log n) typically does more work per item than an O(n) algorithm for the same purpose, but it's still preferrable in most situations because it scales a lot better.

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@Guffa: Thank you for pointing that out! # I fixed it in my question. --- The main problem is still unsolved about how you can deduce, for instance O(n^2). – Masi Jun 28 '09 at 11:31
It's just math, based on the assumption that the amount of work per item is the same. See my edit above. – Guffa Jun 28 '09 at 11:51
@Thank you for your update! --- The key point in your answer is "the assumption that the work per item is the same". – Masi Jun 28 '09 at 12:06

if you can do 10,000,000 ops per second, then when you set n = 500,000 and calculate n * log(n) = 500,000 * log2(500,000) = 500,000 * 18 = 9,000,000 ops which is roughly 10,000,000 for the purposes of the "seconds" classification.

Similarly, with n = 3,000 you get n^2 = 9,000,000. So on every line the number of operations is roughly the same.

share|improve this answer
@Antti: So you take the base value of 10M from O(n). You then try to find an integer solution for n such that we get 10M. --- You made an assumption that the base of log is 2. --- Is it a standard in CS that we use the base of 2, not for instance 10? – Masi Jun 28 '09 at 17:13
Well the fancy thing about big O Notation is that any logarithm is the same in big O. This is due to the definition of big O which is asymptotic domination, when you say that some algorithm is O(n) or O(n log(n)) what you're really saying is that for some positive constant c, the algorithm your algorithm's complexity is <= c*n. From this we can deduce that log_2(n) is O(log_10(n)) and vice versa, because log_2(n)=log_10(n)*log_10(2). In general though log is presumed to be of base 2, because this is how must algorithms scale, although if you're analyzing something like trisort it's log_3 – JSchlather Jun 28 '09 at 17:46
@Masi For asymptotic complexity it doesn't matter if you take log10 or log2 but CS people just use log2 out of their sleeve because (1) binary search is actually log2 and (2) they anyway think in terms of powers of two. – Antti Huima Jun 28 '09 at 18:17
@Liberalkid: The following is not true: log_2(n)=log_10(n)*log_10(2). --- You can easily deduce then a contradiction by getting 1/lg_10(2) = lg_10(2) => ... => 10 = 2 which is a contradiction. – Masi Jun 28 '09 at 19:30
log_2(n) = log_10(n) * log_2(10) – sth Jun 29 '09 at 5:15

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