I have 4 grids:

  1. kgrid which is [77x1]
  2. x which is [15x1]
  3. z which is [9x1]
  4. s which is [2x1]

Then I have a function:

  1. kprime which is [77x15x9x2]

I want to interpolate kprime at some points ksim (750 x 1) and zsim (750 x 1) (xsim is a scalar). I am doing:

[ks, xs, zs, ss] = ndgrid(kgrid, x, z, [1;2]);
Output = interpn(ks, xs, zs, ss, kprime, ksim, xsim, zsim, 1,'linear');

The problem with this interpolation is that the output given is for all combinations of ksim and zsim, meaning that the output is 750x750. I actually need an output of 750x1, meaning that instead of interpolation at all combinations of ksim and zsim I only need to interpolate at ksim(1,1) and zsim(1,1), then ksim(2,1) and zsim(2,1), then ksim(3,1) and zsim(3,1), etc.

In other words, after getting Output I am doing:

Output = diag(squeeze(Output));

I know I can use this output and then just pick the numbers I want, but this is extremely inefficient as it actually interpolates on all other points which I actually do not need. Any help appreciated.

  • 1
    Please provide sample inputs so that we can actually run your code.
    – Oleg
    Aug 31, 2016 at 8:47

3 Answers 3


tl;dr: Change xsim and (ssim) from scalars to vectors of the same size as ksim and zsim

Output = interpn (ks, xs, zs, ss,           ...
                  kprime,                   ...
                  ksim,                     ...
                  repmat(xsim, size(ksim)), ... % <-- here
                  zsim,                     ...
                  repmat(1, size(ksim)),    ... % <-- and here


The ksim, xsim, zsim, and ssim inputs all need to have the same shape, so that at each common position in that shape, each input acts as an "interpolated subscript" component to the interpolated object. Note that while they all need to have the same shape, this shape can be arbitrary in terms of size and dimensions.

Conversely, if you pass vectors of different sizes (after all, a scalar is a vector of length 1), these get interpreted as the components of an ndgrid construction instead. So you were actually telling interpn to evaluate all interpolations on a grid defined by the vectors ksim, and zsim (and your singletons xsim and ssim). Which is why you got a 2D-grid-looking output.

Note that the same scheme applies with the constructing vectors as well (i.e. ks, xs, zs and ss) i.e. you could have used "vector syntax" instead of "common shape" syntax to define the grid instead, i.e.

Output = interpn(kgrid, x, z, s, kprime, % ...etc etc

and you would have gotten the same result.

  • 4
    Well, this probably turned sour for no reason. To be honest I did read the documentation very carefully and did not fulyl get it. @TasosPapastylianou answer helped me much more than tvo. tvo did not tell me anything I had not read yet.
    – phdstudent
    Sep 2, 2016 at 9:32
  • Sorry I lost my temper last night, re-reading this I think I was on quite a short fuse :/ Glad you found it useful volcompt. Sep 2, 2016 at 9:42
  • I think that all this series of comments can be deleted, they do not contribute anything for this post. However, congrats Tasos, you recognized right what was missig for the OP.
    – EBH
    Sep 2, 2016 at 9:46
  • @volcompt If you would have replied to the comments by me and EBH on my answer, we could have helped you two days ago. There's no need to start complaining about that now. This answer is essentially the same solution as mine, but admittedly easier to apply (because it has the code). From your comments, it was clear you know about the use of repmat, so you had all the ingredients. Next time, if something's not clear, just say why. You'll find it easier to get help... And be respectful to the people who try to help you.
    – tvo
    Sep 2, 2016 at 13:52
  • @tvo, I agree, and apologies for my silence but I had a family emergency which precluded my from checking stackoverflow.
    – phdstudent
    Sep 2, 2016 at 13:55

From the documents:

Query points, specified as a real scalars, vectors, or arrays.

  • If Xq1,Xq2,...,Xqn are scalars, then they are the coordinates of a single query point in Rn.
  • If Xq1,Xq2,...,Xqn are vectors of different orientations, then Xq1,Xq2,...,Xqn are treated as grid vectors in Rn.
  • If Xq1,Xq2,...,Xqn are vectors of the same size and orientation, then Xq1,Xq2,...,Xqn are treated as scattered points in Rn.
  • If Xq1,Xq2,...,Xqn are arrays of the same size, then they represent either a full grid of query points (in ndgrid format) or scattered points in Rn.


You want the usage highlighted in bold. As such, you have to make sure that xsim and ssim ('1' in your code sample) are of size 750x1 also. Then all the query vectors are same length and orientation, such that it can be recognized as a vector of scattered points in Rn. The output will then be a 750x1 vector as needed.

  • Yes, the issue is that indeed xsim is a scalar and not a vector. I can use repmat to repeat it several times but I do not think that's what I need.
    – phdstudent
    Aug 30, 2016 at 18:33
  • @volcompt You also have to do it for the second-to-last argument in your code sample: '1'. Then the output will be a 750x1 vector, and there is no more need to remove any interpolated data. This is what you want right? Otherwise, you need to clarify your question.
    – tvo
    Aug 30, 2016 at 18:52
  • @volcompt this answer is quite straightforward. For xsim and all other scalars, don't use repmat but repelem or simply multiply them by vec where vec is predifined as vec = ones(750,1).
    – EBH
    Sep 1, 2016 at 9:01
  • @EBH what is the advantage of repelem or multiplying with ones over repmat? Is it faster, if so why?
    – tvo
    Sep 1, 2016 at 15:52
  • @tvo See my answer here
    – EBH
    Sep 1, 2016 at 19:25

This is to elaborate on @tvo/@Tasos answers, to test the fastest way to create a vector from a scalar:

function create_vector(n)
x = 5;
repm_time = timeit(@()repm(x,n))
repe_time = timeit(@()repe(x,n))
vrep_time = timeit(@()vrep(x,n))
onesv_time = timeit(@()onesv(x,n))

function A = repm(x,n)
for k = 1:10000
    A = repmat(x,[n 1]);

function A = repe(x,n)
for k = 1:10000
    A = repelem(x,n).';

function A = vrep(x,n)
v = ones(n,1);
for k = 1:10000
    A = x*v;

function A = onesv(x,n)
for k = 1:10000
    A = x*ones(n,1);

And the results are (for n = 750):

repm_time =
repe_time =
vrep_time =
onesv_time =

which means that the fastest way to create a vector from a scalar is simply writing x*ones(n,1).

  • 1
    Interesting, just a slight difference between repmat and repelem, but an order of magnitude faster with ones. Also the difference between 3 and 4 is remarkable, and counterintuitive.
    – tvo
    Sep 1, 2016 at 19:30
  • I was mostly surprised by that * operator by itself (vrep) takes more time then calling it with ones (onesv).
    – EBH
    Sep 1, 2016 at 19:35
  • 1
    You mean that 0.0041342 > 0.0024869, right? The former is dominated by the multiplication I assume. The latter is a combination of multiplying with executing ones(n,1). My guess is that Matlab optimizes x*ones-type expressions, where x*v requires 'full' matrix multiplication.
    – tvo
    Sep 1, 2016 at 19:47

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