why we always consider large value of input in analysis of algorithm for eg:in bigoh notation ?

The point of BigO notation is precisely to work out how the running time (or space) varies as the size of input increases  in other words, how well it scales. If you're only interested in small inputs, you shouldn't use BigO analysis... aside from anything else, there are often approaches which scale really badly but work very well for small inputs. 


Because the worst case performance is usually more of a problem than the best case performance. If your worst case performance is acceptable your algorithm will run fine. 


Analysis of algorithms does not just mean running them on the computer to see which one is faster. Rather it is being able to look at the algorithm and determine how it would perform. This is done by looking at the order of magnitude of the algorithm. As the number of items(N) changes what effect does it have on the number of operations needed to execute(time). This method of classification is referred to as BIGO notation.



It's because of the definition of BigO notation. Given O(f(n)) is the bounds on g([list size of n]): For some value of n, n0, all values of n, n0 < n, the runtime or space complexity of g([list]) is less than G*f(n), where G is an arbitrary constant. What that means is that after your input goes over a certain size, the function will not scale beyond some function. So, if f(x) = x (being eq to O(n)), n2 = 2 * n1, the function i'm computing will not take beyond double the amount of time. Now, note that if O(n) is true, so is O(n^2). If my function will never do worse than double, it will never do worse than square either. In practice the lowest order function known is usually given. 


Big O says nothing about how well an algorithm will scale. "How well" is relative. It is a general way to quantify how an algorithm will scale, but the fitness or lack of fitness for any specific purpose is not part of the notation. 

