# Algorithm design manual solutions error?

I've read about Big O notation from many sources, including Skiena and the Wikipedia entry, the Example section of which states:

In typical usage, the formal definition of O notation is not used directly; rather, the O notation for a function f(x) is derived by the following simplification rules:

• If f(x) is a sum of several terms, the one with the largest growth rate is kept, and all others omitted.

• If f(x) is a product of several factors, any `constants` (terms in the product that do not depend on x) are `omitted`.

The solution to problem 2.2 is O((n^3)/3). Shouldn't the "/3" be omitted, or am I missing something?

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You are correct. 1/3 is a constant, and therefore should omitted.

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You're correct, to be proper, O(n^3 /3) (i.e., O(1/3 * n^3)) should have the 1/3 coefficient omitted from the final answer. This is because the 1/3 component of the expression is trivial with extremely large n. This would be a good opportunity to edit Wikipedia and make the correction.

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The constants do not need to be omitted, they just don't carry any information - O(n^3) is the same as O(n^3 / 3). You'll note that the quoted passage discusses typical usage, not rigorous requirements.

Looking at the specific answer, the solution is asymptotically equivalent to n^3 / 3. While not formally any different than O(n^3), I'd guess the idea is to provide more specific information by giving O(n^3 / 3).

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en.wikipedia.org/wiki/Big_O_notation read the example section. I now is no difference, but if it is represented as Big O, the rules should be respected. –  croisharp Nov 16 '11 at 14:31
@croisharp Read the definitions, not the examples. Constants do not need to be eliminated. –  Michael J. Barber Nov 16 '11 at 14:34
Multiplying a function by a constant can not affect its asymptotic behavior, because we can multiply the bounding constants in the Big Oh analysis of c · f(n) by 1/c to give appropriate constants for the Big Oh analysis of f(n). Thus: O(c · f(n)) → O(f(n)). The algorithm Design Manual, page 40. Anyway, thanks for answer. –  croisharp Nov 16 '11 at 14:38
@croisharp Sounds like we're in perfect agreement. O(c · f(n)) → O(f(n)) and O(f(n)) → O(c · f(n)); the constants might as well be eliminated, but don't have to be. –  Michael J. Barber Nov 16 '11 at 14:41
Ok, it is not a must, but it should be omitted as Daniel said. –  croisharp Nov 16 '11 at 14:44

Not must, positive constant factors are allowed in O-notation. They are just pointless and therefore should be omitted.

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Let me give an example.

``````suppose we have function,
f(n)=1/3 * (4n^3) + 4n^2+ 1

lets gather all the facts...

we know that ,
for all sufficient large value of n>=1
1/3 * (4n^3) <= 1/3 *  4n^3

for all sufficient large value of n>=1
4n^2 <= 1/3 * 12n^3

and similarly, for all sufficent large value of n>=1
1 <= 1/3 * 5n^3

thus we can conclude that,
1/3 * (4n^3) + 4n^2+ 1  <= 1/3 * 4n^3 + 1/3 * 12n^3+1/3 * 5n^3   , where n >=1

lets simplify it,
1/3 * (4n^3) + 4n^2+ 1  <= (1/3) * 21n^3
f(n)   <= (1/3) * 21n^3
f(n)   <= ((1/3)*21)*n^3
f(n)   <= (7)*n^3
f(n)   = O(n^3) , where c=7 and n0=1

if we don't include 1/3 in c than,
f(n)   <= (1/3) * 21n^3
f(n)   <=  (21)*(n^3 /3)
f(n)   = O(n^3 /3), where c=21 and n0=1

so the constant value 'c' will be changed.
``````
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