# Crystallography Miller indices remove equivalent indices from list

I'm doing a bit of crystallographic calculation with Miller indices (hkl), i.e. integer triples (hkl) stored here in an int[] array. I'm using C#. I could so far if I set a maximum hmax, kmax, and lmax fill a list containing all equivalents:

List<int[]> milind = new List<int[]>;
int[] mindex = new int[3];
for ( int h = -hmax ; h <= hmax; h++)
{
mindex[0] = h;
for ( int k = -kmax ; k <= kmax; k++)
{
mindex[1] = k;
for ( int l = -lmax ; l <= lmax; l++)
{
mindex[2] = l;
}
}
}


QUESTION: How can I remove/filter all equivalents, i.e. permutations of one set [h,k,l] using C#?

EXAMPLE: Let's say we have [h=1,k=0,l=0], I want to remove/filter: [0,1,0], [0,0,1], [-1,0,0], [0,-1,0], [0,0,-1] ... etc. leaving only [0,0,1] in the list.

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Define a "canonical" form for your indices such as this:

• [h] is largest magnitude index,with sign +1;
• [k] is second largest magnitude index;
• [l] is remaining index
• all common factors have been factored out

Now convert all your indices to their canonical form, and eliminate them if they are a duplicate of one already found.

This form also allows for sorting of your Miller indices, speeding up searchng, etc.

I have a physics degree; I knew Miller indices couldn't get too large. ;-)

Here is a "Canonization" procedure. It uses brute force for the factorization, but I believe that is sufficient for the problem domain; if performance is an issue that can be addressed later.

2013-03-09: Updated to use pre-computed table of primes <= 31

  public struct MillerIndex {
public int H { get; private set; }
public int K { get; private set; }
public int L { get; private set; }

public MillerIndex( int h, int k, int l) : this() {
H = h;  K = k;  L = l;
}
}

public static class MillereHandler {

static IList<int> Primes = new List<int> {2,3,5,7,11,13,17,19,23,29,31};

public static MillerIndex GetCanonical(MillerIndex mi) {
int h, k, l, sign;
if (Math.Abs(mi.H) > Math.Abs(mi.K) && Math.Abs(mi.H) >  Math.Abs(mi.L) ) {
sign = Math.Sign(mi.H);
h = mi.H;
k = Math.Abs(mi.K) > Math.Abs(mi.L) ? mi.K : mi.L;
l = Math.Abs(mi.K) > Math.Abs(mi.L) ? mi.L : mi.K;
} else if (Math.Abs(mi.K) > Math.Abs(mi.H) && Math.Abs(mi.K) >  Math.Abs(mi.L) ) {
sign = Math.Sign(mi.K);
h = mi.K;
k = Math.Abs(mi.H) > Math.Abs(mi.L) ? mi.H : mi.L;
l = Math.Abs(mi.H) > Math.Abs(mi.L) ? mi.L : mi.H;
} else {
sign = Math.Sign(mi.L);
h = mi.L;
k = Math.Abs(mi.H) > Math.Abs(mi.K) ? mi.H : mi.K;
l = Math.Abs(mi.H) > Math.Abs(mi.K) ? mi.K : mi.H;
}

h *= sign;  k *= sign;  l *= sign;

foreach (var i in Primes.Where(i=> (i^2) < l) ) {
while ( (h/i)*i == h  &&  (k/i)*i == k &&  (l/i)*i == l ) {
h /= h/i;  k /= k/i;  l /= l/i;
}
}

return new MillerIndex(h, k, l);
}
}

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How can I implement this in C#? I'm quite new in the C# business. – user2143695 Mar 7 '13 at 18:57
I am running out to do some errands. Make a stab at it and I will check back with you in 90 minutes or so. – Pieter Geerkens Mar 7 '13 at 19:02
Ok I'll try my best. – user2143695 Mar 7 '13 at 19:12
Oh, I forget to mention that hmax, kmax, and lmax are all about 100. – user2143695 Mar 7 '13 at 20:31
Hmm, I could create new Miller indices by invoking e.g. MillerIndex mi = new MillerIndex(1,0,0); but how would that integrate in my loop? At the moment, however, I could not figure this out. – user2143695 Mar 7 '13 at 21:13

I just want to add to Pieter's answer. It is not correct to cancel out common factors. A (200) reflection is different from a (100) one. So all the effort with prime numbers is not necessary.

If you have cubic symmetry, the easiest way to generate the canonical form would be to make all indices positive by taking the absolute value and then sorting the three numbers. Thus [0,-2,-1] -> [0,2,1] -> [0,1,2]

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