I have a question about the difference between polynomial time algorithms, non polynomial time algorithms and exponential time algorithms for example if an algorithm will take O(n^2) time then which category will it be in?
check this out
http://en.wikipedia.org/wiki/Big_oh#Orders_of_common_functions
exponential is worse than polynomial.
O(n^2) falls into the quadratic category, which is a type of polynomial (the special case of the exponent being equal to 2) and better than exponential.
Exponential is much worse than polynomial. Look at how the functions grow
n = 10  100  1000
n^2 = 100  10000  1000000
k^n = k^10  k^100  k^1000
k^1000 is exceptionally huge unless k is smaller than something like 1.1. Like, something like every particle in the universe would have to do 100 billion billion billion operations per second for trillions of billions of billions of years to get that done.
I didn't calculate it out, but ITS THAT BIG.

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3k^1000 is exceptionally huge if k is appreciably larger than 1. If k=1 it's less impressive, and if k=1.00069387..., it's 2. – Josephine Nov 30 '10 at 19:53


1How about n! vs k^n. I know for 2^n(most common), n! will be more expensive, but i believe for a general k^n where k>2, n! will be less expensive. – Saad Jul 17 '16 at 23:44

Below are some common BigO functions while analyzing algorithms.
 O(1)  constant time
 O(log(n))  logarithmic time
 O((log(n))^{c})  polylogarithmic time
 O(n)  linear time
 O(n^{2})  quadratic time
 O(n^{c})  polynomial time
 O(c^{n})  exponential time
(n = size of input, c = some constant)
Here is the model graph representing BigO complexity of some functions
cheers :)
graph credits http://bigocheatsheet.com/

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O(n^2) is polynomial time. The polynomial is f(n) = n^2. On the other hand, O(2^n) is exponential time, where the exponential function implied is f(n) = 2^n. The difference is whether the function of n places n in the base of an exponentiation, or in the exponent itself.
Any exponential growth function will grow significantly faster (long term) than any polynomial function, so the distinction is relevant to the efficiency of an algorithm, especially for large values of n.

This answer has an authoritative (good) air, but it differs from @dheeran's answer, I believe, in whether the base in the exponential case is necessarily 2. Or probably I misunderstand and just need to dust off my algebra. – Tom Russell Apr 25 '18 at 7:18
Polynomial time.
A polynomial is a linear combination of terms that look like Constant * x^k
On the opposite, exponential means something like k^x
, where in both case k is a constant and x is a variable.
Exponential algorithms execution time grows much faster than that of polynomial ones.
Exponential (You have an exponential function if MINIMAL ONE EXPONENT is dependent on a parameter):
 E.g. f(x) = constant ^ x
Polynomial (You have a polynomial function if NO EXPONENT is dependent on some function parameters):
 E.g. f(x) = x ^ constant

2I don't like it if nothing from my original answer is left after it has been edited by a user. Is this some kind of "likefishing"? – Erhard Dinhobl Dec 10 '14 at 10:20

2
polynomial time O(n)^k means Number of operations are proportional to power k of the size of input
exponential time O(k)^n means Number of operations are proportional to the exponent of the size of input
o(n sequre) is polynimal time complexity while o(2^n) is exponential time complexity if p=np when best case , in the worst case p=np not equal becasue when input size n grow so long or input sizer increase so longer its going to worst case and handling so complexity growth rate increase and depend on n size of input when input is small it is polynimal when input size large and large so p=np not equal it means growth rate depend on size of input "N". optimization, sat, clique, and independ set also met in exponential to polynimal.