# Find most equidistant path through points with fixed number of points — with better than O(N!)

complete rewrite:

I have an array of integers (I'm calling them points) of length N (they represent indexes into an array). I want to pick X points from the N values where X < N such that the points are the most equidistant as possible. I've had trouble defining how to measure that, but I think variance is the key now.

For example, the ideal path is:

``````[5, 10, 15, 20] (distance is 5)
``````

If you prefer, you can think of them as 2D points:

``````[(0, 5), (1, 10), (2, 15), (3, 20)]
``````

But my actual N values to choose from may be something like:

``````[4, 6, 10, 13, 15, 17, 21]
``````

And I want to select X (4 in this example) where their distances to each other are "the most equidistant". At the moment, I'm defining that as "the smallest variance when the distance is compared to the ideal distance," but am open to other definitions.

I think that's enough to describe my problem sufficiently. The rest that follows describes how I get to this point, which does have some assumptions about optimizing the equidistance:

I'm currently trimming my selection of points by looking at the ideal points/distances and removing any points as candidates that are outside of a given threshold.

e.g.,

If my width is 10 and I want two points, my ideal list of points is [10, 20]. But I may have [1, 9, 22, 25, 1000] available. If my (somewhat arbitrary) trim threshold is 5, I remove 1 and 1000, leaving me [9, 22, 25] (and an eventual answer of [9, 22])

I also expand the list of points if needed if there is nothing near the ideal point. So if I have a threshold of 5, width of 10 and only have [1, 21], then I will add in a 10 due to having no candidates near 10. 1 is thrown out due to trimming. The eventual answer would be [10, 21]

Here's a graphical representation as I'm realizing now geometry is a large component and why I also gave a 2D representation. In the following picture the blue line is the ideal equidistant selection of points. The error bars represent the trimming threshold. (All other points trimmed are not represented)

Now, how do I select the 5 points in this graph that most closely approximates the blue line?

I have an O(N!) answer below.

Example for furins:

Let's say our ideal is [ 10, 20, 30, 40, 50] and our existing points are [10,15,25,32,39,42,50]. Our existing points give us these possible combinations of paths, with threshold=5.

(20 could be replaced with 15 or 25, 30 can only be replace with 32, 40 could be replaced with 39 or 42)

``````[ 10, 15, 32, 39, 50 ] -> widths: 5, 17, 7, 11
[ 10, 15, 32, 42, 50 ] -> widths: 5, 17, 10, 8
[ 10, 25, 32, 39, 50 ] -> widths: 15, 7, 7, 11
[ 10, 25, 32, 42, 50 ] -> widths: 15, 7, 10, 8
``````

Can't use average width to pick the best -- I get the same values, so I use variance to compare them. Variance from desired width sum of (width-10)^2:

``````(10-5)^2 + (10-17)^2 + (10-6)^2 + (10-12)^2 = 25 + 49 + 9 + 1 = 84
... = 25 + 49 + 0 + 4 = 79
... = 25 + 9 + 9 + 1 = 44
... = 25 + 9 + 0 + 2 = 36
``````

To me, the optimal spacing is the last one with the smallest variance, 36. But 36 uses 42, not 39 -- 39 is the closest to 40. So this tells me you need to look beyond just the closest points to the ideal and how that points affects points beyond.

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You've got a lot of poorly (if at all) defined things here: "close enough" appears in a number of different contexts. And how do you balance the percentage of desired values vs closeness to 75? –  Scott Hunter Jan 8 '14 at 17:38
I defined "close enough" precisely in an example: "If my distance criteria for "close enough" is ±10, then we arrive at the following..." -- ah, but ±10 was the wrong value from an earlier edit. It should be ±5. –  rrauenza Jan 8 '14 at 18:18
in the example of threshold of 5, width of 10 and only have [1, 21] why do you trim 1 and keep 21? Is [1,11] an acceptable answer as well? For the same reason, when you say If my width is 10 and I want two points, my ideal list of points is [10, 20] why [0,10] or [3,13] are not ideal answers? –  furins Jan 9 '14 at 20:15
what if list = [1, 5, 15, 25, 45], width = 10 and threshold = 5 and you want 4 points? what are the expected alternative results? –  furins Jan 9 '14 at 20:19
Let me see if I can reconcile this... I'm initially given what I call an ideal set of points, say, [10, 20, 30, 40], width=10. But I have existing points around that ideal set of points that I may want to use instead -- if they are within the threshold. So points within the treshold near 10 are considered as alternates to 10, points within the threshold near 20 are considered as alternates to 20, etc. Does that clarify things? –  rrauenza Jan 10 '14 at 0:14

The naive answer seems to be to iterate over the X length combinations of N points (pick X from N) and find the smallest variance when comparing the distances to the ideal.

But that is O(N!).

Less naive, but still O(N!)-ish is to reduce the possibilities and make a list of possible path combinations. Trimming is done by only selecting values within a given distance of the ideal value (an input into the process).

Then iterate over all combinations and find the minimum variance relative to the ideal distance of the ideal path (10 for [0, 10, 20, 30, 40] in this example):

``````[(4,3), (15,12), (21,15), (30,35), (43,41,35)]
``````

For example,

``````[ 4, 15, 21, 30, 43 ]
[ 4, 15, 21, 30, 41 ]
[ 4, 15, 21, 30, 35 ]
[ 4, 15, 21, 35, 43 ]
[ 4, 15, 21, 35, 35 ]
...
``````

itertools.product() in Python does this well:

``````# Assume we have already trimmed and turned our possible
# paths into a list of choices, [(4 or 3), (15 or 12), ...]
for path in itertools.product((4,3), (15,12), (21,15), (30,35), (43,41,35)):
var = calc_variance(path, ideal_distance)
if var < bestvar:
bestpath = path
bestvar = var
``````

But it is still O(N!), but N is now bound by the trim distance.

-

basing on your edited question and on your comments, this code should fit your needs. I'm not a CS so I'm unsure of the O() estimation but according to my understanding the first loop is O(N) and the list comprehension at the end converges to O(X) and it may not be greater than O(N). I'm assuming X < N (as is in your question)

``````# parameters needed to define the "ideal list"
# in this example the ideal list is [5, 25, 45, 65]
x = 4
width = 10.0
starting_idx = 10

# other parameters
e = width/2  # maximum allowable error (absolute value)

# now I calculate the ideal list
ideal_list = [int(starting_idx + width*i) for i in range(0,x+1)]

#... and the population
nList = [10,15,25,32,39,42,50]

ideals = dict((j,[]) for j in ideal_list)

# swap the comments in the following two lines if x*width ~ n
# for point in nList:
for point in [el for el in nList if (el >= (e - starting_idx)) and (el <= (e + starting_idx + width*(x-1)))]:
idx = int(round((point-starting_idx)/width)*width+starting_idx) # idx is the closest ideal value
difference = abs(point-idx)  # this is the difference from the ideal value
if (difference <= e):  # if the difference is less than the threshold...
ideals[idx].append((point, difference))  # ... let's save a tuple

result=sorted([min(v, key = lambda t: t[1])[0] if len(v)>0 else k for k,v in ideals.items()])
print result
``````

the code works fine when `e > width/2`, it may return less values than in your graphical example when `e == width/2` since I'm using `round` so I cannot have a number that is at the same time close to two ideal values (in the graph you have 15 and 35 belonging to two different sets of desired points). If `e > width`, the threshold parameter `e` has no effects.

since I do not have to take in account the overall variance, but only the relative distances to ideal points for each subset, I do not have to use `itertools.product` and thus I'm not falling into the O(N!) case

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Thanks furins -- I'm still trying to tease apart your algorithm ... (Still looking at it) –  rrauenza Jan 13 '14 at 16:51
FYI, Your result line doesn't parse under the python I'm using -- is it 3? It seems like your algorithm is picking the point within the threshold nearest the ideal point. I'll add to the main body because I need the extra formatting. –  rrauenza Jan 13 '14 at 17:01
the code parses correctly on python2.7, the only point that may not work in python3 seems the print statement without parenthesis. You're correct the algorithm picks the point within the threshold nearest the ideal point because that is the point that generate the most "equidistant" list (I have discovered a truly marvelous proof of this, which this comment is too narrow to contain). If you want your formatting you may change the second last line: `result=sorted([min(v, key = lambda t: t[1])[0] if len(v)>0 else k for k,v in ideals.items()])` –  furins Jan 13 '14 at 17:27
I would like to say that part of your question is based on a wrong assumption: when you ask "Now, how do I select the 5 points in this graph that most closely approximates the blue line?" the answer is the one given by my code, you are searching for N points that lay closer to a line than any other else, but non necessarily the blue line you plot. –  furins Jan 13 '14 at 21:05
I think that picking the nearest point doesn't always most closely approximate the line either. Because the point you pick at the Xth point influences the distance the line is at X+1th point. No maybe not. At one point I was thinking of this as the line with the most similar distances... but that was a mistake. But it led me to the idea of the variance of the distances compared to the ideal distance. Let me dwell some more on the geometric equivalent. –  rrauenza Jan 13 '14 at 21:37