I found basic MATLAB implementation of the 2D gamma index in Appendix A of this thesis.

I copy/pasted the following code from the thesis, and I made a couple of simplifications for readability. I talked to the author and confirmed that my version of the code (below) is correct. Recently, I have been using this code in the analysis portion of a medical physics study that I'll be publishing soon.

The inputs `A1`

and `A2`

are 2D arrays (which, in practice, are dose maps or fluence maps). We let `A1`

serve as the reference data, and `A2`

is the data that is being evaluated. If we use a typical 2%, 2mm acceptance criterion, then we set distance to agreement as `DTA=2mm`

, and we set the dose threshold `dosed=0.02`

, which is 2%.

In this simple implementation, we assume that the array indices are spaced in 1mm increments. If your data doesn't use 1mm increments, then scale your `dosed`

value accordingly (e.g. if your `A1`

and `A2`

are in 0.5mm increments, then use `DTA=4`

to get a 2mm criterion).

The output, `G`

, is a 2D array of gamma values.

```
function G = gamma2d (A1, A2, DTA, dosed)
size1=size (A1) ;
size2=size (A2) ;
dosed = dosed * max(A1 ( : ) ) ; %scale dosed as a percent of the maximum dose
G=zeros ( size1 ) ; %this will be the output
Ga=zeros ( size1 ) ;
if size1 == size2
for i = 1 : size1( 1 )
for j = 1 : size1( 2 )
for k = 1 : size1( 1 )
for l = 1 : size1( 2 )
r2 = ( i - k )^2 + (j - l) ^2 ; %distance (radius) squared
d2 = ( A1( i , j ) - A2( k , l ) )^2 ; %difference squared
Ga( k , l ) = sqrt(r2 / (DTA^2) + d2/ dosed ^ 2);
end
end
G( i , j )=min(min(Ga)) ;
end
end
else
fprintf=('matrices A1 and A2 are do not share the same dimensions! \n')
end
end
```

To see an explanation of the gamma index in math notation, I recommend looking at this blog post.