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Sample Sub-optimal output

I am trying to write an application that generates drawing for compartmentalized Panel.

I have N cubicles (2D rectangles) (N <= 40). For each cubicle there is a minimum height (minHeight[i]) and minimum width (minWidth[i]) associated. The panel itself also has a MAXIMUM_HEIGHT constraint.

These N cubicles have to be arranged in a column-wise grid such that the above constraints are met for each cubicle.

Also, the width of each column is decided by the maximum of minWidths of each cubicle in that column.

Also, the height of each column should be the same. This decides the height of the panel

We can add spare cubicles in the empty space left in any column or we can increase the height/width of any cubicle beyond the specified minimum. However we cannot rotate any of the cubicles.

OBJECTIVE: TO MINIMIZE TOTAL PANEL WIDTH.

At present I have implemented it simply by ignoring the widths of cubicles in my optimization. I just choose the cubicle with largest minHeight and try to fit it in my panel. However, it does not gurantee an optimal solution.

Can I get any better than this?

EDIT 1: MAXIMUM_HEIGHT of panel = 2100mm, minwidth range (350mm to 800mm), minheight range (225mm to 2100mm)

EDIT 2: PROBLEM OBJECTIVE: TO MINIMIZE PANEL WIDTH (not panel area).

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  • I'm trying to wrap my mind around the height part of the problem. Do you stack cubicles? Do you have to provide stairs or a ladder to the cubicles on top? Aug 30, 2013 at 17:13
  • Yes the cubicles are stacked one on top the other, making a 'column'. There can be one or more such columns placed side-by-side. Each column should have the same height (viz. <= MAXIMUM_HEIGHT). The MAXIMUM_HEIGHT is 2100mm so no stairs or ladders needed. I'm sorry I didn't understand this part of your query. Aug 30, 2013 at 17:20
  • It is a 2d problem, no 3d element is involved. Aug 30, 2013 at 17:23
  • @GilbertLeBlanc OP is only mentions 2 dimensions (height/width). Maybe think of this as a "wall plan" as opposed to a "floor plan"?
    – NealB
    Aug 30, 2013 at 17:23
  • @NealB yes you are correct in visualizing. Aug 30, 2013 at 17:24

3 Answers 3

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+100

Formulation

Given:

  • for each cell i = 1, ..., M, the (min) width W_i and (min) height H_i
  • the maximum allowed height of any stack, T

We can formulate the mixed integer program as follows:

minimize sum { CW_k | k = 1, ..., N }
with respect to

    C_i in { 1, ..., N },                        i = 1, ..., M

    CW_k >= 0,                                   k = 1, ..., N

and subject to

[1] sum { H_i | C_i = k } <= T,                  k = 1, ..., N

[2] CW_k = max { W_i | C_i = k },                k = 1, ..., N
           (or 0 when set is empty)

You can pick N to be any sufficiently large integer (for example, N = M).

Algorithm

Plug this mixed integer program into an existing mixed integer program solver to determine the cell-to-column mapping given by the optimal C_i, i = 1, ..., M values.

This is the part you do not want to reinvent yourself. Use an existing solver!

Note

Depending on the expressive power of your mixed integer program solver package, you may or may not be able to directly apply the formulation I described above. If the constraints [1] and [2] cannot be specified because of the "set based" nature of them or the max, you can manually transform the formulation to an equivalent less-declarative but more-canonical one that does not need this expressive power:

minimize sum { CW_k | k = 1, ..., N }
with respect to

    C_i_k in { 0, 1 },                           i = 1, ..., M; k = 1, ..., N

    CW_k >= 0,                                   k = 1, ..., N

and subject to

[1] sum { H_i * C_i_k | i = 1, ..., M } <= T,    k = 1, ..., N

[2] CW_k >= W_i * C_i_k,                         i = 1, ..., M; k = 1, ..., N

[3] sum { C_i_k | k = 1, ..., N } = 1,           i = 1, ..., M

Here the C_i variables from before (taking values in { 1, ..., N }) have been replaced with C_i_k variables (taking values in { 0, 1 }) under the relationship C_i = sum { C_i_k | k = 1, ..., N }.

The final cell-to-column mapping is described by the the C_i_k: cell i belongs in column k if and only if C_i_k = 1.

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  • shouldn't the last line be max instead of min? Sep 3, 2013 at 17:08
  • @Heuster Yes, typo. :) Sep 3, 2013 at 17:09
  • Thank You for your answer! Actually I can understand only little bit from the notation. Is N the number of columns? How does it ensure that each Cell occurs in only 1 column? Sorry can you please elaborate your problem formulation? Thanks Again! Sep 3, 2013 at 17:22
  • Oh yes I see, for each cell, I can sum over the columns and make the sum equal to 1. Am I correct? Sep 3, 2013 at 17:24
  • 2
    +1, an ILP is a good way to solve this problem, which is surely NP-complete. One issue with your formulation is that it does not distinguish permutations of columns, so if the optimal solution has d columns, there will be d! equal-score optimal solutions, which may cause a solver to do more work than necessary. You can fix this by e.g. forcing each column to have height <= the previous column: change constraint 1 from the first formulation to [1a] sum { H_i | C_i = 1 } <= T; [1b] sum { H_i | C_i = k } <= sum { H_j | C_j = k-1 } T for k = 2, ..., N. Sep 4, 2013 at 2:55
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One solution is to divide the width of the cubicle row by the minimum width. This gives you the maximum number of cubicles that can fit in a row.

Divide the remainder of the first division by the number of cubicles. This gives you the extra width to add to the minimum width to make all of the cubicle widths even.

Example: You have a cubicle row of 63 meters. Each cubicle has a minimum width of 2 meters. I'm assuming that the thickness of one of the cubicle walls is included in the 2 meters. I'm also assuming that one end cubicle will be against a wall.

Doing the math, we get 63 / 2 = 31.5 or 31 cubicles.

Now we divide 0.5 meters by 31 cubicles and get 16 millimeters. So, the cubicle widths are 2.016 meters.

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  • Columns don't have to all be the same width. Ie need to put narrow cubicles in narrow columns and wide cubicles in wide columns Aug 30, 2013 at 17:25
  • Also, the minimum width and height of each cubicle is different. (sorry very complicated scenario) :) Aug 30, 2013 at 17:29
  • @AbhishekBansal: Ok, my mistake. You can use the same idea as my answer, except you place the cubicles in the row in sorted minimum width order, descending. You still allocate the left over space to all the cubicles in the row evenly. Aug 30, 2013 at 17:40
  • Yes thanks for your answer. Actually as I said, at present I have implemented it in exactly the same way as you have suggested. But the problem is that there is 2nd dimension as well. For example, it may happen that for the largest minHeight, the minWidth is small and vice-versa. In such a case would this approach be a good one? Aug 30, 2013 at 17:44
  • @AbhishekBansal: I have still not figured out how height figures into placing cubicles. You're going to have to post a photograph and show us. Sep 3, 2013 at 12:47
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You can look into vm packing especially share aware algorithm for virtual machine collocation: http://dl.acm.org/citation.cfm?id=1989554. You can read also about @ http://en.m.wikipedia.org/wiki/Bin_packing_problem. The problem is already difficult but the cubicle can share width or height. Thus the search space gets bigger.

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