# What is the algorithm used to interpolate in Matlab's imresize function?

I am using the Matlab/Octave `imresize()` function which resamples a given 2D array. I want to understand how a particular interpolation algorithm used in `imresize` works.

(I am using octave on windows)

e.g.

``````A =  1 2
3 4
``````

is a 2D array. Then I use the command

``````b=imresize(a,2,'linear');
``````

basically upsampling row and columns by 2.

The output is

``````1.0000   1.3333   1.6667   2.0000
1.6667   2.0000   2.3333   2.6667
2.3333   2.6667   3.0000   3.3333
3.0000   3.3333   3.6667   4.0000
``````

I don't understand how this linear interpolation is working. It is said to use bilinear interpolation, but how does it pad the data at boundaries and how does it get the output that it is getting?

Second example: For

``````A =

1   2   3   4
5   6   7   8
0   1   2   3
1   2   3   4
``````

how does `imresize(a,1.5,'linear')` give the following output?

``````1.00000   1.60000   2.20000   2.80000   3.40000   4.00000
3.40000   4.00000   4.60000   5.20000   5.80000   6.40000
4.00000   4.60000   5.20000   5.80000   6.40000   7.00000
1.00000   1.60000   2.20000   2.80000   3.40000   4.00000
0.40000   1.00000   1.60000   2.20000   2.80000   3.40000
1.00000   1.60000   2.20000   2.80000   3.40000   4.00000
``````
-

As you can see, in your example, each corner point is one of your original input values.

The intermediate values are derived via linear interpolation in each direction. So for instance, to calculate `b(3,2)`:

• `b(1,2)` is 1/3 of the way between `b(1,1)` and `b(1,4)`. So:

``````b(1,2) = (1/3)*b(1,4) + (2/3)*b(1,1)
``````
• `b(4,2)` is 1/3 of the way between `b(4,1)` and `b(4,4)`. So:

``````b(4,2) = (1/3)*b(4,4) + (2/3)*b(4,1)
``````
• `b(3,2)` is 2/3 of the way between `b(1,2)` and `b(4,2)`. So:

``````b(3,2) = (2/3)*b(4,2) + (1/3)*b(1,2)
``````
-
@Oli - Thanks. I get it. I assume, The calculation of weights for a different scaling factor would take the appropriate values. i.e. For my example the weights were 0.33,0.66 since 2 given samples were to be interpolated to 4 samples total, if it was 2 samples to be interpolated to total N samples, weights would be 1/(N-1), 2/(N-1) isn't it? –  goldenmean Jun 22 '11 at 14:55
@OliCharlesworth - Edited OP to add a second example which resamples by a fractional scaling factor,. In that case not clear how it comptued its outputs. Can u pls. check above. –  goldenmean Jun 22 '11 at 15:06
@Oli - Any inputs about the second example which I added in OP? –  goldenmean Jun 22 '11 at 15:32
@Oli - also in you edited answer points b(4,2) and b(3,2) computations look incorrect (weights swapped) to me. Isn't it? –  goldenmean Jun 22 '11 at 15:39
@goldenmean: Yes, good spot, I had that last calculation back to front! –  Oliver Charlesworth Jun 22 '11 at 15:48

The following code shows how to perform bilinear interpolation using INTERP2:

``````A = [1 2; 3 4];
SCALE = 2;

xi = linspace(1,size(A,2),SCALE*size(A,2));  %# interpolated horizontal positions
yi = linspace(1,size(A,1),SCALE*size(A,1));  %# interpolated vertical positions
[X Y] = meshgrid(1:size(A,2),1:size(A,1));   %# pixels X-/Y-coords
[XI YI] = meshgrid(xi,yi);                   %# interpolated pixels X-/Y-coords
B = interp2(X,Y,A, XI,YI, '*linear');        %# interp values at these positions
``````

the result agrees with your Octave code output:

``````B =
1       1.3333       1.6667            2
1.6667            2       2.3333       2.6667
2.3333       2.6667            3       3.3333
3       3.3333       3.6667            4
``````

I should mention that I'm getting different results between MATLAB and Octave IMRESIZE output. For example, this is what I get when I execute the following in MATLAB on the matrix `A=[1 2; 3 4]`:

``````>> B = imresize([1 2; 3 4], 2, 'bilinear')
B =
1         1.25         1.75            2
1.5         1.75         2.25          2.5
2.5         2.75         3.25          3.5
3         3.25         3.75            4
``````

which suggests that MATLAB's implementation is doing something extra... Unfortunately it's not easy to read the IMRESIZE source code, especially since at some point it calls a MEX-compiled function (with no source code form available).

As a side note, there seems to be a older version of this function as well: IMRESIZE_OLD (purely implemented in m-code). From what I could understand, it performs some sort of affine transformation on the image. Perhaps someone more familiar with the technique could shed some light on the subject...

-
My guess is Matlab runs a Gaussian filter on the input data before upsampling. Octave does not do that(Although octave mentions that in the help imresize, but does not do that, when I checked. –  goldenmean Jun 23 '11 at 8:39
@goldenmean: that would explain the difference. In any case, and to answer your original question, the Wikipedia article I linked to explains well the bilinear interpolation process with an example.. –  Amro Jun 23 '11 at 11:25
I took a second look at the IMRESIZE function, please read my answer to this other question: stackoverflow.com/questions/7758078/… –  Amro Oct 13 '11 at 20:29

I adapted MATLAB's `imresize` function for Java:

``````import java.util.ArrayList;
import java.util.List;

public class MatlabResize {
private static final double TRIANGLE_KERNEL_WIDTH = 2;

public static double[][] resizeMatlab(double[][] data, int out_y, int out_x) {
double scale_x = ((double)out_x)/data[0].length;
double scale_y = ((double)out_y)/data.length;

double[][][] weights_indizes = contribution(data.length, out_y, scale_y, TRIANGLE_KERNEL_WIDTH);
double[][] weights = weights_indizes[0];
double[][] indices = weights_indizes[1];

final double[][] result = new double[out_y][data[0].length];
double value = 0;

for (int p=0; p<result[0].length; p++) {
for (int i=0; i<weights.length; i++) {
value = 0;

for (int j=0; j<indices[0].length; j++) {
value += weights[i][j] * data[(int)indices[i][j]][p];
}

result[i][p] = value;
}
}

weights_indizes = contribution(data[0].length, out_x, scale_x, TRIANGLE_KERNEL_WIDTH);
weights = weights_indizes[0];
indices = weights_indizes[1];

final double[][] result2 = new double[result.length][out_x];
for (int p=0; p<result.length; p++) {
for (int i=0; i<weights.length; i++) {
value = 0;

for (int j=0; j<indices[0].length; j++) {
value += weights[i][j] * result[p][(int)indices[i][j]];
}

result2[p][i] = value;
}
}

return result2;
}

public static double[][] resizeMatlab(double[][] data, double scale) {
int out_x = (int)Math.ceil(data[0].length * scale);
int out_y = (int)Math.ceil(data.length * scale);

double[][][] weights_indizes = contribution(data.length, out_y, scale, TRIANGLE_KERNEL_WIDTH);
double[][] weights = weights_indizes[0];
double[][] indices = weights_indizes[1];

final double[][] result = new double[out_y][data[0].length];
double value = 0;

for (int p=0; p<result[0].length; p++) {
for (int i=0; i<weights.length; i++) {
value = 0;

for (int j=0; j<indices[0].length; j++) {
value += weights[i][j] * data[(int)indices[i][j]][p];
}

result[i][p] = value;
}
}

weights_indizes = contribution(data[0].length, out_x, scale, TRIANGLE_KERNEL_WIDTH);
weights = weights_indizes[0];
indices = weights_indizes[1];

final double[][] result2 = new double[result.length][out_x];
for (int p=0; p<result.length; p++) {
for (int i=0; i<weights.length; i++) {
value = 0;

for (int j=0; j<indices[0].length; j++) {
value += weights[i][j] * result[p][(int)indices[i][j]];
}

result2[p][i] = value;
}
}

return result2;
}

private static double[][][] contribution(int length, int output_size, double scale, double kernel_width) {
if (scale < 1.0) {
kernel_width = kernel_width/scale;
}

final double[] x = new double[output_size];
for (int i=0; i<x.length; i++) {
x[i] = i+1;
}

final double[] u = new double[output_size];
for (int i=0; i<u.length; i++) {
u[i] = x[i]/scale + 0.5*(1 - 1/scale);
}

final double[] left = new double[output_size];
for (int i=0; i<left.length; i++) {
left[i] = Math.floor(u[i] - kernel_width/2);
}

int P = (int)Math.ceil(kernel_width) + 2;

final double[][] indices = new double[left.length][P];
for (int i=0; i<left.length; i++) {
for (int j=0; j<=P-1; j++) {
indices[i][j] = left[i] + j;
}
}

double[][] weights = new double[u.length][indices[0].length];
for (int i=0; i<u.length; i++) {
for (int j=0; j<indices[i].length; j++) {
weights[i][j] = u[i] - indices[i][j];
}
}

if (scale < 1.0) {
weights = triangleAntiAliasing(weights, scale);
} else {
weights = triangle(weights);
}

double[] sum = Matlab.sum(weights, 2);
for (int i=0; i<weights.length; i++) {
for (int j=0; j<weights[i].length; j++) {
weights[i][j] = weights[i][j] / sum[i];
}
}

for (int i=0; i<indices.length; i++) {
for (int j=0; j<indices[i].length; j++) {
indices[i][j] = Math.min(Math.max(indices[i][j], 1.0), length);
}
}

sum = Matlab.sum(weights, 1);
int a = 0;

final List<Integer> list = new ArrayList<Integer>();
for (int i=0; i<sum.length; i++) {
if (sum[i] != 0.0) {
a++;
}
}

final double[][][] result = new double[2][weights.length][a];
for (int i=0; i<weights.length; i++) {
for (int j=0; j<list.size(); j++) {
result[0][i][j] = weights[i][list.get(j)];
}
}
for (int i=0; i<indices.length; i++) {
for (int j=0; j<list.size(); j++) {
result[1][i][j] = indices[i][list.get(j)]-1; //java indices start by 0 and not by 1
}
}

return result;
}

private static double[][] triangle(final double[][] x) {
for (int i=0; i<x.length; i++) {
for (int j=0; j<x[i].length; j++) {
if (-1.0 <= x[i][j] && x[i][j] < 0.0) {
x[i][j] = x[i][j] + 1;
} else if (0.0 <= x[i][j] &&  x[i][j] < 1.0) {
x[i][j] = 1 - x[i][j];
} else {
x[i][j] = 0;
}
}
}

return x;
}

private static double[][] triangleAntiAliasing(final double[][] x, final double scale) {
for (int i=0; i<x.length; i++) {
for (int j=0; j<x[i].length; j++) {
x[i][j] = x[i][j] * scale;
}
}

for (int i=0; i<x.length; i++) {
for (int j=0; j<x[i].length; j++) {
if (-1.0 <= x[i][j] && x[i][j] < 0.0) {
x[i][j] = x[i][j] + 1;
} else if (0.0 <= x[i][j] &&  x[i][j] < 1.0) {
x[i][j] = 1 - x[i][j];
} else {
x[i][j] = 0;
}
}
}

for (int i=0; i<x.length; i++) {
for (int j=0; j<x[i].length; j++) {
x[i][j] = x[i][j] * scale;
}
}

return x;
}
}
``````
-
So are you saying your code is equivalent to the MATLAB `imresize` code? Did you somehow reverse-engineer the MEX-compiled function that Amro mentioned? Or did you just in general implement a similar functionality without verifying that it produces identical results in different corner cases? –  Jonas Heidelberg Feb 2 '12 at 21:43
Hm.. equivalent.. :) I tried to understand the `imresize` function in MATLAB and port it for JAVA. (The sourcecode of this function is readable). With this function i got (for 600x600 matrices resized to 192x192) the same results like in MATLAB. But i didn't tested it with unit-tests. –  lee.O Feb 2 '12 at 22:32