Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am studying the book Introduction to Algorithms, by Thomas H. Corman. I am studying the asymptotic notation. One thing is bothering me, because the author stated that:

f(n)=Big-theta(g(n)) implies f(n)=Big-O(g(n)) , since Big-theta notation is stronger notion than O-notation. HOW??

and the author also stated that (an^2+bn+c), where a>0, is in Big-theta(n^2) also shows that such quadratic function is in Big-O(n^2). HOW??

share|improve this question
    
This is a duplicate of a number of other questions: stackoverflow.com/questions/3230122/big-oh-vs-big-theta stackoverflow.com/questions/471199/… –  ulmangt Sep 9 '12 at 4:44
    
@ulmangt; the couple of the same links I searched ,didn't find any answer that could have clear my confusion. that's why I asked it SO. –  kTiwari Sep 9 '12 at 4:47

2 Answers 2

I think you are confused a bit with the terms.

f(n) = O(g(n)) - means that g(n) is an upper bound of f(n). Formally - exist const n0, c, such that for all n>n0, f(n)<= c*g(n). You can imagine it as two graphs, such that c*g(n) is upper than f(n). For example : 5n^2+n = O(n^2)

Why ?

Because if, for example, n0=10 and c=10, then for all n>n0 - 5n^2+n <= 10*n^2

f(n) = Theta(g(n)) - means that g(n) is an upper and a lower bound of f(n). Formally - exist const n0, c1, c2, such that for all n>n0, c1*g(n)<=f(n)<=c2*g(n). You can imagine it as three graphs, such that f(n) is between c1*g(n) and c2*g(n). For example : 5n^2+n = Theta(n^2)

Why ?

Because if, for example, n0=100 and c1=1,c2=100 then for all n>n0 - n^2<=5n^2+n<=100*n^2

share|improve this answer

(In V1 of the book) the definition of f() being in Theta(g(n)) is that there are positive constants C1 and C2 such that 0 <= C1g(n) <= f(n) <= C2g(n) for all n >= N0

The definition of O(g(n)) is that there is a single C such that 0 <= f(n) <= Cg(n) for all n >= N0

So if you can find big enough constants N0, C1 and C2 to satisfy the first definition, you can use constants N0 and C = C2 to satisfy the second definition. Therefore the first definition is stronger than the second in the sense that anything that satisfies the first satisfies the second - and the business about the quadratic is a special case of this.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.