# dynamic programing

Im trying to understand part of a question I have as my HW but it's really looks like chinese...

Lets say we have coins `x_1,x_2,x_3...xn`

x_1 = 1 always. and we want to give a certain amount of money in minimum number of coins. Than we use dynamic programing .

And now I don't understand this - `c(i,j) = min { c(i-1,j), 1+c(i,j-x_i)` where c(i,j) is the minimal amount of coins to return amount j.

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What don't you understand? `c(i,j)` is the recursive formula, you do an exhaustive search - for each coin you check what is better - to take it, or not to take it – amit Nov 7 '12 at 16:28
@amit why it is the minimal between those 2?? – Bobbbaa Nov 7 '12 at 16:30
Because you are looking for the minimal number of coins, by checking all possible solutions, you get the minimal overall. – amit Nov 7 '12 at 16:32
@amit this is not what I mean... why possible solution is 1+c(i,j-x_i)?? where does it come from? – Bobbbaa Nov 7 '12 at 16:38
`c(i,j-x_i)` is the minimal number of coins to get the value `j-x_i` using only coins `i,i+1,...,n` (This is the induction hypothesis, that's what the recursive formula ensures us). Thus, `1+c(i,j-x_i)` is the minimal way to get `j-x_i` with the given set of coins + an extra coin valued `x_i`, which we decided to use. – amit Nov 7 '12 at 16:52

`c(i,j-x_i)` is the minimal number of coins to get the value `j-x_i` using only coins `i,i+1,...,n` (This is the induction hypothesis, that's what the recursive formula ensures us).
Thus, `1+c(i,j-x_i)` is the minimal way to get `j-x_i` with the given set of coins + an extra coin valued `x_i`, which we decided to use.
From this, `c(i,j) = min { c(i-1,j), 1+c(i,j-x_i) }` is actually choosing "what is best" exhaustively:
Taking the minimal of those ensures us (because it is done exhaustively - over all possibilities) that `c(i,j)` is minimal.