I'm having trouble dealing with memoization and the bottom up approach algorithm for this problem:

suppose you have an array of elements `xi`

such that `-10000 < xi < 10000`

,for all `0 < i < N`

. Try to find maximum sum of T elements,T < N such that they are arranged in different sub-arrays.We don't sum the first element in each sub-array ,and we have to return the numbers K of sub-arrays as well.

An example should explain :

```
T=4,
array = 3 9 1 1 7 => (3 9) and (1 7) have maximum sum 16= 9 + 7 ,K = 2
```

```
T=4,
array = 3 9 6 3 7 => (3 9 6 3) have maximum sum 18 = 9 + 6 + 3 , K = 1
```

*T = 9, array = 14 11 18 1 1 16 12 18 0 0 11 18 9 5 14 => the contiguous sub-arrays are (14 11 18) (1 16 12 18) (11 18) K=3 and max_sum=11 + 18 + 16 + 12 + 18 + 18 = 93 ** **for T=15 array = 6 19 -29 15 9 -4 5 27 3 12 -10 5 -2 27 10 -2 11 23 -4 5 => the contiguous sub-arrays are (6 19) (-29 15 9) (5 27 3 12) (-2 27 10) (-2 11 23) with K =5 and max_sum= 19 + 15 + 9 + 27 + 3 + 12 +27 + 10 + 11 + 23=156

This is what I've done so far :

`let f[i][j][0] denotes the maximal sum for the first i slots and using j slots, and the i-th slot is not used.`

`let f[i][j][1] denotes the maximal gain for the first i slots and using j slots , and the i-th slot is used.`

obviously, `f[i][j][k]`

can determine `f[i+1][j][k]`

or `f[i+1][j+1][k]`

details:

```
f[i+1][j+1][1]=max(f[i+1][j+1][1],f[i][j][0],f[i][j][1]+G[i+1]);
f[i+1][j][0]=max(f[i+1][j][0],f[i][j][0],f[i][j][1]);
```

`T=4, array = 3 9 1 1 7 => (3 9 1 1 7) have maximum sum 18 = 9 + 1 + 1 + 7, K = 1`

? – anatolyg Mar 17 '13 at 13:02T=4, array = 3 9 1 1 7we have to peek 4 elements,and the best solution is **(3 9) and (1 7) ** because 7 + 9 = 16 and first element of each sub-array ( 3 and 1) don't matter.In any other cases we had obtained a smaller sum.I hope this makes it much clear. :) – Mougart Mar 17 '13 at 13:28