I would think about building the solution one step at a time, inductively:

Coins available are 1c, 5c, 10c, 25c (you can tweak them according to your needs)

- Minimun coins for 1c = 1 X 1c. Upto 4 cents, we need 1c coins, as that is the least denomination.
- For 5 cents, we have one 5c coin. Combining that with 4c above, we can generate any number between 1 and 9.
- For 10 cents, we need 1 X 10c. Combining the above three, we can generate any number between 1 and 19.
- For 20c, we need 2 x 10c, as 20 is divisible by 10.

If you can formulate the problem inductively, it might be easier to tackle it.

**EDIT:**

Alright, here's another attempt to explain the dynamic programming solution:

Think of a table with `x`

rows (`x`

is number of distinct denominations) and `n`

columns (`n`

is the amount you have to build using least denominations). Every cell in this table represents a distinct sub-problem and will eventually contain the solution to it. Assume:

row 1 represents the set `{1c}`

i.e. in row 1 you are allowed to use infinite `1c`

row 2 represents the set `{1c, 10c}`

i.e in row 2 you are allowed to infinite `1c`

and `10c`

row 3 represents the set `{1c, 10c, 15c}`

and so on...

Each column represents the amount you want to construct.

Thus, every cell corresponds to one small sub-problem. For example (the indexes are starting from 1 for the sake of simplicity),

`cell(1, 5)`

==> construct `5c`

using only `{1c}`

`cell(2, 9)`

==> construct `9c`

using `{1c, 10c}`

`cell(3, 27)`

==> construct `27c`

using `{1c, 10c, 15c}`

Now your aim is to get the answer to `cell(x, n)`

`Solution:`

Start solving the table from the simplest problem. Solving the first row is trivial, since in the first row the only denomination available is `{1c}`

. Every cell in row 1 has a trivial solution, leading to `cell(1, n)`

= `{nx1c}`

(`n`

coins of `1c`

).

Now proceed to the next row. Generalizing for the 2nd row, lets see how to solve for (say) `cell(2, 28)`

i.e. construct `28c`

using `{1c, 10c}`

. Here, you need to make a decision, whether to include `10c`

in the solution or not, and how many coins. You have 3 choices (3 = 28/10 + 1)

`Choice 1`

:

Take `{1x10c}`

and the rest from the previous row (which is stored in `cell(1, 18)`

). This gives you `{1x10c, 18x1c}`

= `19 coins`

`Choice 2`

:

Take `{2x10c}`

and the rest from previous row (which is stored in `cell(1, 8)`

). This gives you `{2x10c, 8x1c}`

= `10 coins`

`Choice 3`

:

Take no `10c`

and the rest from the previous row (which is stored in `cell(1, 28)`

). This gives you `{28x1c}`

= `28 coins`

Clearly, choice 2 is the best as it takes less coins. Write it down in the table and proceed ahead. The table is to be filled one row at a time, and within a row, in the order of increasing amounts.

Going by above rules, you will reach `cell(x, n)`

, the solution to which will be a choice between `n/p + 1`

alternatives, where `p`

= newest denomination in row `x`

. The best choice is your answer.

The table actually memoizes the solutions to smaller problems, so that you don't need to solve them again and again.