Imagine you're working through the array A, selecting values to include in your subsequence. At each step, you can either (a) include the current value, or (b) not include it. If you memoize the better of these two options, then it should be possible to get dynamic programming working.

In pseudocode, your function should look something like this:

```
int longest_subseq(ix, available_weight, last_val):
# Parameters:
# ix = an index into array A (assumed to have global scope)
# available_weight = the remaining weight avaiable for the subsequence
# starting at ix
# last_val = the last value in the subsequence from A[0] through A[ix-1]
# When first called, create a DP array of 10^5 × 51 × 51 elements
# (This will use about 1GB of memory, which I assume is OK)
if DP is undefined:
DP = new array(100001, 51, 51)
initialize every element of DP to -1
# Return memoized value if available
v = DP[ix, available_weight, last_val]
if v >= 0:
return v
# Check for end conditions
if ix == n or available_weight == 0:
return 0
# Otherwise you have two options; either include A[ix] in the
# subsequence, or don't include it
len0 = longest_subseq(ix+1, available_weight, last_val)
if abs(A[ix] - last_val) > available_weight:
DP[ix, available_weight, last_val] = len0
return len0
len1 = 1 + longest_subseq(ix+1, available_weight-abs(A[ix]-last_val), A[ix])
if len0 > len(1):
DP[ix, available_weight, last_val] = len0
return len0
else:
DP[ix, available_weight, last_val] = len1
return len1
```

If you then call `longest_subseq(0, k, A[0])`

, the function should return the correct answer in a reasonable amount of time.