## Simplifying

First I want to simplify the problem, to do that:

- I switch the axes and add them to each other, this results in x2 growth
- I assume it is parabola on a closed interval
`[a, b], where a = 0`

and for this example `b = 3`

Lets say you are given `b`

(second part of interval) and `w`

(width of a segment), then you can find total number of segments by `n=Floor[b/w]`

. In this case there exists a trivial case to maximize Riemann sum and function to get i'th segment height is: `f(b-(b*i)/(n+1)))`

. Actually it is an assumption and I'm not 100% sure.

Max'ed example for `17`

segments on closed interval `[0, 3]`

for function `Sqrt[x]`

real values:

And the segment **heights** function in this case is `Re[Sqrt[3-3*Range[1,17]/18]]`

, and values are:

{Sqrt[17/6], 2 Sqrt[2/3], Sqrt[5/2],
Sqrt[7/3], Sqrt[13/6], Sqrt[2],
Sqrt[11/6], Sqrt[5/3], Sqrt[3/2],
2/Sqrt[3], Sqrt[7/6], 1, Sqrt[5/6],
Sqrt[2/3], 1/Sqrt[2], 1/Sqrt[3],
1/Sqrt[6]}

{1.6832508230603465,
1.632993161855452, 1.5811388300841898, 1.5275252316519468, 1.4719601443879744, 1.4142135623730951, 1.35400640077266, 1.2909944487358056, 1.224744871391589, 1.1547005383792517, 1.0801234497346435, 1, 0.9128709291752769, 0.816496580927726, 0.7071067811865475, 0.5773502691896258, 0.4082482904638631}

What you have archived is a **Bin-Packing problem**, with partially filled bin.

## Finding b

If `b`

is unknown or our task is to find smallest possible `b`

under what all sticks form the initial bunch fit. Then we can limit at least `b`

values to:

- lower limit : if sum of segment heights = sum of stick heights
- upper limit :
~~number of segments = number of sticks ~~ longest stick < longest segment height

One of the simplest way to find `b`

is to take a pivot at `(higher limit-lower limit)/2`

find if solution exists. Then it becomes new higher or lower limit and you repeat the process until required precision is met.

When you are looking for `b`

you do not need exact result, but suboptimal and it would be much faster if you use efficient algorithm to find relatively close pivot point to actual `b`

.

For example:

- sort the stick by length: largest to smallest
- start 'putting largest items' into first bin thy fit

decision problem. For a problem to be NP-complete, it has to be in NP, which are decision problems (they all have yes/no answers). However, it could beNP-hard, meaning it's at least as hard as any problem in NP. You could phrase this as a decision problem "given lengths and some parabola, can you fit them in height at most h?" to make this a candidate NP-complete problem. – templatetypedef Feb 22 '11 at 22:52