## In general

To prove that an optimization problem can be solved using a greedy algorithm, we need to prove that the problem has the following:

**Optimal substructure property**: an optimal global solution contains the optimal solutions of all its subproblems.

**Greedy choice property**: a *global* optimal solution can be obtained by greedily selecting a *locally* optimal choice.

## Example

Let us consider the classical **activity selection problem**. We have a set *S* of *n* activities, each one with a start time `s[i]`

and an end time `e[i]`

. We want to choose a subset of S, such that the selection **maximizes the number of non overlapping events**.

This problem can be solved using a greedy algorithm, but how can we **prove** that?

We need to show it exhibits:

Consider a general activity *a* contained in a global optimal solution `S = {A', a, A''}`

, where `S`

is the global optimal solution, *a* is our little activity, and `A'`

and `A''`

are two subproblems of finding the activities *before* a and *after* a.

If the problem has the optimal substructure property, **the optimal solution for the subproblems **`A'`

and `A''`

must be contained in the global optimal solution `S`

.

This is true, but why?

Suppose that the optimal solution for the subproblem `A'`

is not in `S`

. Then we could substitute the optimal for `A'`

, say `S'`

, in `A`

, to obtain a new global optimal solution that is better than `S`

. But `S`

was the global optimal solution! Contradiction.

We need to prove that our greedy choice (to select the activity that ends first) is correct.

Let `B`

be a subproblem. Let *b* be the activity of the subproblem `B`

that ends first, thus *b* is our (first) greedy choice. **We need to prove that ***b* is included in some optimal solution for `B`

.

Let `X`

be an optimal solution for the subproblem `B`

. Let *x* be the activity in `X`

that ends first.

If *b* = *x*, then *b* is in `X`

, the optimal solution for `B`

, and we have shown that the greedy choice is included in the optimal solution.

If *b* != *x*, surely we have that `end_time[b] < end_time[x]`

.

Since *b* was our greedy choice (i.e. the activity that ends first of all in the subproblem `B`

), then we can substitute `x`

with *b* in `X`

to obtain another optimal solution: `X' = (X \ {x}) U {b}`

. `X'`

is optimal because it has the same number of activities of `X`

, and `X`

was optimal, and in this case, *b* is in `X'`

, the optimal solution for `B`

.

So our greedy choice `b`

is included in some optimal solution for `B`

in one case or the other.

## Matroids

Furthermore, there's a powerful mathematical theory that can be **in some case** used to mechanically prove that a particular problem can be solved with a greedy approach.

Briefly:

One can define a particular combinatoric structure named **matroid**.

Some smart man proved in the past that these **matroids have the Optimal substructure property and the Greedy choice property**.

This means that you can run a greedy algorithm on your optimization problem, and it will find the optimal solution. You only need to **verify that your problem is defined on a matroid-like structure**.

Further information about this can be found here.