# solving an equation where some unknowns must be integers

Solve for s, and t1tn that minimizes the following summation:

Σnk = 1 (1 - min(s·tk,Ck)/max(s·tk,Ck)),

where

C1Cn > 1, s > 0, t1tn ∈ ℤ+

edit to clarify to problem description:

"how fast of an algorithm you require." Not super fast (But not multiple seconds). n will be around 5-10 or so.

As far as the actual problem, I have a number of "elements" of different sizes on a "page" and this page needs to be translated to a format in which there is a maximum base size for an element of X, and the base size of an element has to be an integer. However in the new format any element can be scaled up by a single scaling factor set for the page.

So C1...Cn were the sizes of the elements on the original page. t1...tn are the new integer sizes in the new page format. (And t1...tn need to be less than X.) The scaling factor for the new page format is s.

More:

As far as what I've done previously, I find the largest element on the original page, and if its smaller than X, I just use the existing element sizes on the new page, but rounding each one to an integer. However, If the largest element on the original page is greater than X, I divide its size by X to get the scaling factor s for the new page, and divide C1...Cn by s to get t1...tn. But this results in size discrepancies of something like 1-3% on average for every element on the new page but the largest. Not really all that noticeable, but I'm a perfectionist.

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Without mentioning some computer language or CAS, this is off topic. The word you need for Googling is 'Diophantine'. –  AakashM Jun 8 '10 at 7:01
It is not off topic- are alogirithms tied to some specific computer language - thanks for the reference to diophantine, though. To others - please don't be presumptious and misguided about labelling something homework when you don't know what you are talking about. –  Mark Jun 8 '10 at 7:03
@Mark, the part: "when you don't know what you are talking about" sound a bit like biting the hand that (possibly) feeds you, besides the fact that it's just plain unfriendly. –  Bart Kiers Jun 8 '10 at 7:08
FYI to all: this concerns an actual program - I just distilled the problem down to a compact form - is it suddenly legitimate now. –  Mark Jun 8 '10 at 7:09
Personally I think this is a legit question, just that it's missing some information, like what are the limits on `s`, `ti`, `Ci` and `n`, and also how fast of an algorithm you require. Also, posting the initial problem might help, because there might be a simpler solution to it than minimizing this sum. I think you show add more information to your question, and not settle on answers. Only accept answers that actually solve your problem. –  IVlad Jun 8 '10 at 8:06
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You should read on linear programming with integer unknowns as well. Even though this is not linear programming it might give you an idea on what to look for.

Also you might head over to http://mathoverflow.net/ to get some help remodelling the problem (you have an optimization problem on an integer domain with discontinuities in goal function and my math is a bit rusty to place it properly; check combinatorial optimization as well)

(for the right solution jump to EDIT4 below)
EDIT: Regarding linearity

Looking for maximum of

Σnk = 1 (1 - min(s·tk,Ck)/max(s·tk,Ck))

might be the same as looking at the maximum for

Σnk = 1 (max(s·tk,Ck) - min(s·tk,Ck))

providing that

Σnk = 1 max(s·tk,Ck) > 0

(which is always ?true? given your conditions)

And term

Σnk = 1 (max(s·tk,Ck) - min(s·tk,Ck))

can be written as

Σnk = 1 Abs(s·tk - Ck)

which, if the question mark above hold gives the following

• maximize s and all tk
• minimize all Ck

So all C = 1, and all t and s → ∞ for which your original expression approaches n.

Ok, so originally I was wrong with my suggestion, because I assumed a question would not degenerate into trivial case, which actually it quite obviously does.

EDIT2: My math is rusty, the procedure above is not correct (first step), but the conclusion/solution seems to validate so I will not correct (it gets a bit complicated)

EDIT3 (Ck are constants and other corrections):

Maybe I should clean up the answer, I believe the following reasoning is enough as a solution:

The fact that Ck are constant and not equal 1 does not matter. To maximize original expression

Σnk = 1 (1 - min(s·tk,Ck)/max(s·tk,Ck))

you should minimize

Σnk = 1 min(s·tk,Ck)/max(s·tk,Ck)

since domain of everything is positive to make this ratio minimal you have to make numerator as small as possible and denominator as big as possible.

The ratio is zero if

• tk is 0 for all k ⇒ min(0, Ck)/max(0, Ck) = 0/Ck = 0

It also approaches zero if

• s approaches zero (similarly as above, only it is the limit that is equal 0)
• s approaches infinity ⇒ min(∞, Ck)/max(∞, Ck) = Ck/∞ = 0
(the above equalities should have used limit notation...)
• tk approaches infinity for all k

(each condition is enough on its own and represents the solution, when combining them don't let s approach 0 while tk approach infinity or vice versa; in such case it matters which one approaches it faster)

EDIT4: (actual solution)
Well basically all of the above is giving answer to a wrong question, because I was looking for maximum of the original goal function, not the minimum.

As for minimum it is a bit more interesting, the minimum is reached if each term

min(s·tk,Ck)/max(s·tk,Ck) = 1

This is the maximum of this term given the domain of the parameters. If we assume (for now) that Ck is integer then the solution can be found for

s = 1
tk=Ck

However Ck is not integer in general case, so we need to find s for which Ck/s is integer.

If we can write Ck as

Nk/Dk where N, D ∈ ℤ+ (in another words if Ck is rational)

then a solution can be

s = 1/∏nk = 1Dk
tk = Nk/Dk · ∏nk = 1Dk (which is ∈ ℤ+)

Note: Instead of choosing s to be a product of all denominators it could be set to biggest common denominator, and then tk can be calculated appropriately.

Note2: Plotting diagrams of the functions in question helped me catch my error of misreading the question (realizing that minimum is much more interesting). Also I realized that the functions are continuous (but not smooth, so derivations are discontinuous).

Note3: The above solution works for rational numbers, but I imagine that irrational numbers would not make the solution useless as decimal or other rational representations of irrational numbers would give an approximate solution proportionally close to real solution as the representation is close to actual value of irrational number.

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The api lp_solve mentioned in the wikipedia article looked promising until I read the following in the documentation: "Also note that both objective function and constraints must be linear equations. This means that no variables can be multiplied with each other." So as you say, what I'm doing is non-linear. Specifically its "Mixed Integer Nonlinear Programming (MINLP)", a term I discovered just now: "[It] refers to mathematical programming with continuous and discrete variables and nonlinearities in the objective function and constraints." –  Mark Jun 8 '10 at 9:24
except in my case only the objective function is nonlinear –  Mark Jun 8 '10 at 9:29
@Mark, updated the answer –  Unreason Jun 8 '10 at 11:23
Thanks for pointing out that the original objective formula can be rewritten as summation(abs((s*tk)-ck). "So all C = 1, and all t and s → ∞ for which your original expression approaches n." Its only your conclusion here I believe that is incorrect. C1..Cn are constant. I cannot assume some value for them though. I've edited the OP, btw. –  Mark Jun 8 '10 at 18:56
Also C1...Cn will all be different sizes; –  Mark Jun 8 '10 at 19:06
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Please use Maple, Mathcad or Sage for that. Here is a list of software, that can help you with it: http://en.wikipedia.org/wiki/Comparison_of_computer_algebra_systems

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What are you saying - I need to purchase some software product - that's not what I had in mind. –  Mark Jun 8 '10 at 7:08
@Mark, no. What FractalizeR suggests is to use a CAS for this. If you'd taken the time to actually click (or read) the link s/he posted, you would have noticed that there are many free products available. It may not be the answer you're looking for, but that doesn't mean it's a perfectly legit answer. –  Bart Kiers Jun 8 '10 at 7:11
Just to be clear, I don't have an isolated math problem I'm trying to solve (for homework or otherwise). I was looking to write code to solve the above, if these are API's or similar then of course that would work. Was hoping someone would give a brief verbal overview of the solution. AakashM did mention Diophantine equations, after of course inexplicably slamming me for posting something off-topic, so I will at least check into Diophantine equations in a moment. –  Mark Jun 8 '10 at 7:25
But anyway, diopantine, CAS - probably enough to get me going here, so thanks to all. –  Mark Jun 8 '10 at 7:37

I think that unreason gave the correct answer. You need to read a book about "Nonlinear Integer Programming". I don't have a good book to recommend you, but you can probably find something by going to the library.

I don't think that lp_solve is not good enough for you, because you cannot rewrite your problem in to a mixed integer Integer linear Programming problem (MILP). Maple and Mathcad is not a good idea, because you are not looking for symbolic algebra package.

My guess us that the book will tell you to do branch and bound. Here is a schematic description:

1) Start out solving a generalized problem where t_k are all real prsitime numbers

minimize Σnk = 1 (1 - min(s·tk,Ck)/max(s·tk,Ck)), under the constrain that s > 0, t1…tn ∈ R+

.You can use a generalized Newtons method to do this. Matlab and scipy provide generalized solvers this out of the box, but be careful because your function may have several local minima.

2) Once you have found this solution, you can do a branch ing step. Choose a variables t_k and an integer number a_k, and solve the following two problems independently

Problem 1 minimize Σnk = 1 (1 - min(s·tk,Ck)/max(s·tk,Ck)), under the constrain that s > 0, t1…tn ∈ R+and t_k <= a_k

Problem 2 minimize Σnk = 1 (1 - min(s·tk,Ck)/max(s·tk,Ck)), under the constrain that s > 0, t1…tn ∈ R+ and t_k >= a_k

3) Keep doing branching steps until you have split your problem in to a set of sub-problems that each have an integer solution. Then you can compare these integer solutions and choose the best one.

As you probably have guessed this description is somewhat schematic. You need good branching rules to branch the correct way, and you need good bounding rules to avoid following branches that arent promising.

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"branch and bound" is a term I keep on encountering as well so thanks –  Mark Jun 8 '10 at 19:04
actually my solution was completely wrong, but I think it might be right now. –  Unreason Jun 9 '10 at 12:21
Unreasons fourth solution looks correct. That was a nice trick. In the special case where all the numbers C_k are decimal numbers with n decimals then he gets s=10^-n and t_k=C_k*10^n. –  nielsle Jun 9 '10 at 13:00