## Asymptotic analysis

This term refers to the analysis of algorithm performance under the assumption that the data the algorithm operates on (the *input*) is, in layman's terms, "large enough that making it larger will not change the conclusion". Although the exact size of the input does not need to be specified (we only need an upper bound), the data set itself *has* to be specified.

Note that so far we have only talked about the *method* of analysis; we have not specified exactly which *quantity* we are analyzing (time complexity? space complexity?), and neither have we specified which *metric* we are interested in (worst case? best case? average?).

In practice the term asymptotic analysis commonly refers to *upper bound time complexity* of an algorithm, i.e. the worst case performance measured by total running time, which is represented by the big-Oh notation (e.g. a sorting algorithm might be `O(nlogn)`

).

## Amortized analysis

This term refers to the analysis of algorithm performance based on a specific sequence of operations that targets the *worst case scenario* -- that is, amortized analysis does imply that the metric is worst case performance (although it still does not say which quantity is being measured). To perform this analysis, we need to specify the *size* of the input, but we do not need to make any assumptions about its form.

In layman's terms, amortized analysis is picking an arbitrary size for the input and then "playing through" the algorithm. Whenever a decision that depends on the input must be made, the worst path is taken¹. After the algorithm has run to completion we divide the calculated complexity by the size of the input to produce the final result.

¹note: To be precise, the worst path *that is theoretically possible*. If you have a vector that dynamically doubles in size each time its capacity is exhausted, "worst case" does not mean to assume that it will need to double upon *every* insertion because the insertions are processed as a sequence. We are allowed to (and indeed must) use known *state* to mathematically eliminate as many "even worse" cases as we can, even while the input remains unknown.

## The most important difference

The critical difference between asymptotic and amortized analysis is that the former is dependent on the input itself, while the latter is dependent on the sequence of operations the algorithm will execute.

Therefore:

- asymptotic analysis allows us to assert that the complexity of the algorithm
*when it is given a best/worst/average case input of size approaching N* is bounded by some function F(N) -- where N is a variable
- amortized analysis allows us to assert that the complexity of the algorithm
*when it is given an input of unknown characteristics but known size N is no worse* than the value of a function F(N) -- where N is a known value