griddedInterpolant

Use griddedInterpolant to interpolate a 1-D data set.

Create a vector of scattered sample points v. The points are sampled at random 1-D locations between 0 and 20.

x = sort(20*rand(100,1));
v = besselj(0,x);

Create a gridded interpolant object for the data. By default, griddedInterpolant uses the 'linear' interpolation method.

F = griddedInterpolant(x,v)

F = 
  griddedInterpolant with properties:

            GridVectors: {[100x1 double]}
                 Values: [100x1 double]
                 Method: 'linear'
    ExtrapolationMethod: 'linear'

Query the interpolant F at 500 uniformly spaced points between 0 and 20. Plot the interpolated results (xq,vq) on top of the original data (x,v).

xq = linspace(0,20,500);
vq = F(xq);
plot(x,v,'ro')
hold on
plot(xq,vq,'.')
legend('Sample Points','Interpolated Values')

Interpolate 3-D data using two methods to specify the query points.

Create and plot a 3-D data set representing the function $\mathit{z}\left(\mathit{x},\mathit{y}\right)=\frac{\sin \left({\mathit{x}}^2+{\mathit{y}}^2\right)}{{\mathit{x}}^2+{\mathit{y}}^2}$ evaluated at a set of gridded sample points in the range [-5,5].

[x,y] = ndgrid(-5:0.8:5);
z = sin(x.^2 + y.^2) ./ (x.^2 + y.^2);
surf(x,y,z)

Create a gridded interpolant object for the data.

F = griddedInterpolant(x,y,z);

Use a finer mesh to query the interpolant and improve the resolution.

[xq,yq] = ndgrid(-5:0.1:5);
vq = F(xq,yq);
surf(xq,yq,vq)

In cases where there are a lot of sample points or query points, and where memory usage becomes a concern, you can use grid vectors to improve memory usage.

Alternatively, execute the previous commands using grid vectors.

x = -5:0.8:5;
y = x';
z = sin(x.^2 + y.^2) ./ (x.^2 + y.^2);
F = griddedInterpolant({x,y},z);
xq = -5:0.1:5;
yq = xq';
vq = F({xq,yq});
surf(xq,yq,vq)

Use the default grid to perform a quick interpolation on a set of sample points. The default grid uses unit-spaced points, so this interpolation is useful when the exact xy spacing between the sample points is not important.

Create a matrix of sample function values and plot them against the default grid.

x = (1:0.3:5)';
y = x';
V = cos(x) .* sin(y);
n = length(x);
surf(1:n,1:n,V)

Interpolate the data using the default grid.

F = griddedInterpolant(V)

F = 
  griddedInterpolant with properties:

            GridVectors: {[1 2 3 4 5 6 7 8 9 10 11 12 13 14]  [1 2 3 4 5 6 7 8 9 10 11 12 13 14]}
                 Values: [14x14 double]
                 Method: 'linear'
    ExtrapolationMethod: 'linear'

Query the interpolant and plot the results.

[xq,yq] = ndgrid(1:0.2:n);
Vq = F(xq,yq);
surf(xq',yq',Vq)

Interpolate coarsely sampled data using a full grid with spacing of 0.5.

Define the sample points as a full grid with range [1, 10] in both dimensions.

[X,Y] = ndgrid(1:10,1:10);

Sample $$f(x,y)=x^2+y^2$$ at the grid points.

V = X.^2 + Y.^2;

Create the interpolant, specifying cubic interpolation.

F = griddedInterpolant(X,Y,V,'cubic');

Define a full grid of query points with 0.5 spacing and evaluate the interpolant at those points. Then plot the result.

[Xq,Yq] = ndgrid(1:0.5:10,1:0.5:10);
Vq = F(Xq,Yq);
mesh(Xq,Yq,Vq);

Compare results of querying the interpolant outside the domain of F using the 'pchip' and 'nearest' extrapolation methods.

Create the interpolant, specifying 'pchip' as the interpolation method and 'nearest' as the extrapolation method.

x = [1 2 3 4 5];
v = [12 16 31 10 6];
F = griddedInterpolant(x,v,'pchip','nearest')

F = 
  griddedInterpolant with properties:

            GridVectors: {[1 2 3 4 5]}
                 Values: [12 16 31 10 6]
                 Method: 'pchip'
    ExtrapolationMethod: 'nearest'

Query the interpolant, and include points outside the domain of F.

xq = 0:0.1:6;
vq = F(xq);
figure
plot(x,v,'o',xq,vq,'-b');
legend ('v','vq')

Query the interpolant at the same points again, this time using the 'pchip' extrapolation method.

F.ExtrapolationMethod = 'pchip';
figure
vq = F(xq);
plot(x,v,'o',xq,vq,'-b');
legend ('v','vq')

Use griddedInterpolant to interpolate three different sets of values at the same query points.

Create a grid of sample points with $-5\le \mathit{X}\le 5$ and $-3\le \mathit{Y}\le 3$.

gx = -5:5;
gy = -3:3;
[X,Y] = ndgrid(gx,gy);

Evaluate three different functions at the query points, and then concatenate the values into a 3-D array. The size of V is the same as the X and Y grids in the first two dimensions, but the size of the extra dimension reflects the number of values associated with each sample point (in this case, three).

f1 = X.^2 + Y.^2;
f2 = X.^3 + Y.^3;
f3 = X.^4 + Y.^4;
V = cat(3,f1,f2,f3);

Create an interpolant using the sample points and associated values.

F = griddedInterpolant(X,Y,V);

Create a grid of query points with a finer mesh size compared to the sample points.

qx = -5:0.4:5;
qy = -3:0.4:3;
[XQ,YQ] = ndgrid(qx,qy);

Interpolate all three sets of values at the query points.

VQ = F(XQ,YQ);

Compare the original data with the interpolated results.

tiledlayout(3,2)
nexttile
surf(X,Y,f1)
title('f1')
nexttile
surf(XQ,YQ,VQ(:,:,1))
title('Interpolated f1')
nexttile
surf(X,Y,f2)
title('f2')
nexttile
surf(XQ,YQ,VQ(:,:,2))
title('Interpolated f2')
nexttile
surf(X,Y,f3)
title('f3')
nexttile
surf(XQ,YQ,VQ(:,:,3))
title('Interpolated f3')