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| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Tue, 28 Dec 2021 18:22:40 -0500 |
| parents | 8c7685d70cf3 |
| children | 79d6280fb00a |
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######################################################################## ## ## Copyright (C) 2000-2022 The Octave Project Developers ## ## See the file COPYRIGHT.md in the top-level directory of this ## distribution or <https://octave.org/copyright/>. ## ## This file is part of Octave. ## ## Octave is free software: you can redistribute it and/or modify it ## under the terms of the GNU General Public License as published by ## the Free Software Foundation, either version 3 of the License, or ## (at your option) any later version. ## ## Octave is distributed in the hope that it will be useful, but ## WITHOUT ANY WARRANTY; without even the implied warranty of ## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ## GNU General Public License for more details. ## ## You should have received a copy of the GNU General Public License ## along with Octave; see the file COPYING. If not, see ## <https://www.gnu.org/licenses/>. ## ######################################################################## ## -*- texinfo -*- ## @deftypefn {} {@var{yi} =} interp1 (@var{x}, @var{y}, @var{xi}) ## @deftypefnx {} {@var{yi} =} interp1 (@var{y}, @var{xi}) ## @deftypefnx {} {@var{yi} =} interp1 (@dots{}, @var{method}) ## @deftypefnx {} {@var{yi} =} interp1 (@dots{}, @var{extrap}) ## @deftypefnx {} {@var{yi} =} interp1 (@dots{}, "left") ## @deftypefnx {} {@var{yi} =} interp1 (@dots{}, "right") ## @deftypefnx {} {@var{pp} =} interp1 (@dots{}, "pp") ## ## One-dimensional interpolation. ## ## Interpolate input data to determine the value of @var{yi} at the points ## @var{xi}. If not specified, @var{x} is taken to be the indices of @var{y} ## (@code{1:length (@var{y})}). If @var{y} is a matrix or an N-dimensional ## array, the interpolation is performed on each column of @var{y}. ## ## The interpolation @var{method} is one of: ## ## @table @asis ## @item @qcode{"nearest"} ## Return the nearest neighbor. ## ## @item @qcode{"previous"} ## Return the previous neighbor. ## ## @item @qcode{"next"} ## Return the next neighbor. ## ## @item @qcode{"linear"} (default) ## Linear interpolation from nearest neighbors. ## ## @item @qcode{"pchip"} ## Piecewise cubic Hermite interpolating polynomial---shape-preserving ## interpolation with smooth first derivative. ## ## @item @qcode{"cubic"} ## Cubic interpolation (same as @qcode{"pchip"}). ## ## @item @qcode{"spline"} ## Cubic spline interpolation---smooth first and second derivatives ## throughout the curve. ## @end table ## ## Adding '*' to the start of any method above forces @code{interp1} ## to assume that @var{x} is uniformly spaced, and only @code{@var{x}(1)} ## and @code{@var{x}(2)} are referenced. This is usually faster, ## and is never slower. The default method is @qcode{"linear"}. ## ## If @var{extrap} is the string @qcode{"extrap"}, then extrapolate values ## beyond the endpoints using the current @var{method}. If @var{extrap} is a ## number, then replace values beyond the endpoints with that number. When ## unspecified, @var{extrap} defaults to @code{NA}. ## ## If the string argument @qcode{"pp"} is specified, then @var{xi} should not ## be supplied and @code{interp1} returns a piecewise polynomial object. This ## object can later be used with @code{ppval} to evaluate the interpolation. ## There is an equivalence, such that @code{ppval (interp1 (@var{x}, ## @var{y}, @var{method}, @qcode{"pp"}), @var{xi}) == interp1 (@var{x}, ## @var{y}, @var{xi}, @var{method}, @qcode{"extrap"})}. ## ## Duplicate points in @var{x} specify a discontinuous interpolant. There ## may be at most 2 consecutive points with the same value. ## If @var{x} is increasing, the default discontinuous interpolant is ## right-continuous. If @var{x} is decreasing, the default discontinuous ## interpolant is left-continuous. ## The continuity condition of the interpolant may be specified by using ## the options @qcode{"left"} or @qcode{"right"} to select a left-continuous ## or right-continuous interpolant, respectively. ## Discontinuous interpolation is only allowed for @qcode{"nearest"} and ## @qcode{"linear"} methods; in all other cases, the @var{x}-values must be ## unique. ## ## An example of the use of @code{interp1} is ## ## @example ## @group ## xf = [0:0.05:10]; ## yf = sin (2*pi*xf/5); ## xp = [0:10]; ## yp = sin (2*pi*xp/5); ## lin = interp1 (xp, yp, xf); ## near = interp1 (xp, yp, xf, "nearest"); ## pch = interp1 (xp, yp, xf, "pchip"); ## spl = interp1 (xp, yp, xf, "spline"); ## plot (xf,yf,"r", xf,near,"g", xf,lin,"b", xf,pch,"c", xf,spl,"m", ## xp,yp,"r*"); ## legend ("original", "nearest", "linear", "pchip", "spline"); ## @end group ## @end example ## ## @seealso{pchip, spline, interpft, interp2, interp3, interpn} ## @end deftypefn function yi = interp1 (x, y, varargin) if (nargin < 2 || nargin > 6) print_usage (); endif method = "linear"; extrap = NA; xi = []; ispp = false; have_xi = false; rightcontinuous = NaN; if (nargin > 2) for i_arg = 1:length (varargin) arg = varargin{i_arg}; if (ischar (arg)) arg = tolower (arg); switch (arg) case "extrap" extrap = "extrap"; case "pp" ispp = true; case {"right", "-right"} rightcontinuous = true; case {"left", "-left"} rightcontinuous = false; otherwise method = arg; endswitch else if (i_arg == 1) xi = arg; have_xi = true; else extrap = arg; endif endif endfor endif if (! have_xi && ! ispp) xi = y; y = x; if (isvector (y)) x = 1:numel (y); else x = 1:rows (y); endif endif ## reshape matrices for convenience x = x(:); nx = rows (x); szx = size (xi); if (isvector (y)) y = y(:); endif szy = size (y); y = y(:,:); [ny, nc] = size (y); xi = xi(:); ## determine sizes if (nx < 2 || ny < 2) error ("interp1: minimum of 2 points required in each dimension"); endif ## check whether x is sorted; sort if not. if (! issorted (x, "either")) [x, p] = sort (x); y = y(p,:); endif if (any (strcmp (method, {"previous", "*previous", "next", "*next"}))) rightcontinuous = NaN; # needed for these methods to work endif if (isnan (rightcontinuous)) ## If not specified, set the continuity condition if (x(end) < x(1)) rightcontinuous = false; else rightcontinuous = true; endif elseif ((rightcontinuous && (x(end) < x(1))) || (! rightcontinuous && (x(end) > x(1)))) ## Switch between left-continuous and right-continuous x = flipud (x); y = flipud (y); endif ## Because of the way mkpp works, it's easiest to implement "next" ## by running "previous" with vectors flipped. if (strcmp (method, "next")) x = flipud (x); y = flipud (y); method = "previous"; elseif (strcmp (method, "*next")) x = flipud (x); y = flipud (y); method = "*previous"; endif starmethod = method(1) == "*"; if (starmethod) dx = x(2) - x(1); else jumps = x(1:end-1) == x(2:end); have_jumps = any (jumps); if (have_jumps) if (strcmp (method, "linear") || strcmp (method, ("nearest"))) if (any (jumps(1:nx-2) & jumps(2:nx-1))) warning ("interp1: multiple discontinuities at the same X value"); endif else error ("interp1: discontinuities not supported for METHOD '%s'", method); endif endif endif ## Proceed with interpolating by all methods. switch (method) case "nearest" pp = mkpp ([x(1); (x(1:nx-1)+x(2:nx))/2; x(nx)], shiftdim (y, 1), szy(2:end)); pp.orient = "first"; if (ispp) yi = pp; else yi = ppval (pp, reshape (xi, szx)); endif case "*nearest" pp = mkpp ([x(1), x(1)+[0.5:(nx-1)]*dx, x(nx)], shiftdim (y, 1), szy(2:end)); pp.orient = "first"; if (ispp) yi = pp; else yi = ppval (pp, reshape (xi, szx)); endif case "previous" pp = mkpp ([x(1:nx); 2*x(nx)-x(nx-1)], shiftdim (y, 1), szy(2:end)); pp.orient = "first"; if (ispp) yi = pp; else yi = ppval (pp, reshape (xi, szx)); endif case "*previous" pp = mkpp (x(1)+[0:nx]*dx, shiftdim (y, 1), szy(2:end)); pp.orient = "first"; if (ispp) yi = pp; else yi = ppval (pp, reshape (xi, szx)); endif case "linear" xx = x; nxx = nx; yy = y; dy = diff (yy); if (have_jumps) ## Omit zero-size intervals. xx(jumps) = []; nxx = rows (xx); yy(jumps, :) = []; dy(jumps, :) = []; endif dx = diff (xx); dx = repmat (dx, [1 size(dy)(2:end)]); coefs = [(dy./dx).', yy(1:nxx-1, :).']; pp = mkpp (xx, coefs, szy(2:end)); pp.orient = "first"; if (ispp) yi = pp; else yi = ppval (pp, reshape (xi, szx)); endif case "*linear" dy = diff (y); coefs = [(dy/dx).'(:), y(1:nx-1, :).'(:)]; pp = mkpp (x, coefs, szy(2:end)); pp.orient = "first"; if (ispp) yi = pp; else yi = ppval (pp, reshape (xi, szx)); endif case {"pchip", "*pchip", "cubic", "*cubic"} if (nx == 2 || starmethod) x = linspace (x(1), x(nx), ny); endif if (ispp) y = shiftdim (reshape (y, szy), 1); yi = pchip (x, y); yi.orient = "first"; else y = shiftdim (y, 1); yi = pchip (x, y, reshape (xi, szx)); if (! isvector (y)) yi = shiftdim (yi, 1); endif endif case {"spline", "*spline"} if (nx == 2 || starmethod) x = linspace (x(1), x(nx), ny); endif if (ispp) y = shiftdim (reshape (y, szy), 1); yi = spline (x, y); yi.orient = "first"; else y = shiftdim (y, 1); yi = spline (x, y, reshape (xi, szx)); if (! isvector (y)) yi = shiftdim (yi, 1); endif endif otherwise error ("interp1: invalid METHOD '%s'", method); endswitch if (! ispp && isnumeric (extrap)) ## determine which values are out of range and set them to extrap, ## unless extrap == "extrap". minx = min (x(1), x(nx)); maxx = max (x(1), x(nx)); xi = reshape (xi, szx); outliers = (xi < minx) | ! (xi <= maxx); # this even catches NaNs if (size_equal (outliers, yi)) yi(outliers) = extrap; yi = reshape (yi, szx); elseif (! isscalar (yi)) yi(outliers, :) = extrap; else warning ("interp1: Unreachable state. Please submit data that produced this warning to bugs.octave.org"); yi(outliers.') = extrap; endif endif endfunction %!demo %! clf; %! xf = 0:0.05:10; yf = sin (2*pi*xf/5); %! xp = 0:10; yp = sin (2*pi*xp/5); %! lin = interp1 (xp,yp,xf, 'linear'); %! spl = interp1 (xp,yp,xf, 'spline'); %! pch = interp1 (xp,yp,xf, 'pchip'); %! near= interp1 (xp,yp,xf, 'nearest'); %! plot (xf,yf,'r',xf,near,'g',xf,lin,'b',xf,pch,'c',xf,spl,'m',xp,yp,'r*'); %! legend ('original', 'nearest', 'linear', 'pchip', 'spline'); %! title ('Interpolation of continuous function sin (x) w/various methods'); %! %-------------------------------------------------------- %! % confirm that interpolated function matches the original %!demo %! clf; %! xf = 0:0.05:10; yf = sin (2*pi*xf/5); %! xp = 0:10; yp = sin (2*pi*xp/5); %! lin = interp1 (xp,yp,xf, '*linear'); %! spl = interp1 (xp,yp,xf, '*spline'); %! pch = interp1 (xp,yp,xf, '*pchip'); %! near= interp1 (xp,yp,xf, '*nearest'); %! plot (xf,yf,'r',xf,near,'g',xf,lin,'b',xf,pch,'c',xf,spl,'m',xp,yp,'r*'); %! legend ('*original', '*nearest', '*linear', '*pchip', '*spline'); %! title ('Interpolation of continuous function sin (x) w/various *methods'); %! %-------------------------------------------------------- %! % confirm that interpolated function matches the original %!demo %! clf; %! fstep = @(x) x > 1; %! xf = 0:0.05:2; yf = fstep (xf); %! xp = linspace (0,2,10); yp = fstep (xp); %! pch = interp1 (xp,yp,xf, 'pchip'); %! spl = interp1 (xp,yp,xf, 'spline'); %! plot (xf,yf,'r',xf,pch,'b',xf,spl,'m',xp,yp,'r*'); %! title ({'Interpolation of step function with discontinuity at x==1', ... %! 'Note: "pchip" is shape-preserving, "spline" (continuous 1st, 2nd derivatives) is not'}); %! legend ('original', 'pchip', 'spline'); %!demo %! clf; %! t = 0 : 0.3 : pi; dt = t(2)-t(1); %! n = length (t); k = 100; dti = dt*n/k; %! ti = t(1) + [0 : k-1]*dti; %! y = sin (4*t + 0.3) .* cos (3*t - 0.1); %! ddys = diff (diff (interp1 (t,y,ti, 'spline'))./dti)./dti; %! ddyp = diff (diff (interp1 (t,y,ti, 'pchip')) ./dti)./dti; %! ddyc = diff (diff (interp1 (t,y,ti, 'cubic')) ./dti)./dti; %! plot (ti(2:end-1),ddys,'b*', ti(2:end-1),ddyp,'c^', ti(2:end-1),ddyc,'g+'); %! title ({'Second derivative of interpolated "sin (4*t + 0.3) .* cos (3*t - 0.1)"', ... %! 'Note: "spline" has continuous 2nd derivative, others do not'}); %! legend ('spline', 'pchip', 'cubic'); %!demo %! clf; %! xf = 0:0.05:10; yf = sin (2*pi*xf/5) - (xf >= 5); %! xp = [0:.5:4.5,4.99,5:.5:10]; yp = sin (2*pi*xp/5) - (xp >= 5); %! lin = interp1 (xp,yp,xf, 'linear'); %! near= interp1 (xp,yp,xf, 'nearest'); %! plot (xf,yf,'r', xf,near,'g', xf,lin,'b', xp,yp,'r*'); %! legend ('original', 'nearest', 'linear'); %! %-------------------------------------------------------- %! % confirm that interpolated function matches the original %!demo %! clf; %! x = 0:0.5:3; %! x1 = [3 2 2 1]; %! x2 = [1 2 2 3]; %! y1 = [1 1 0 0]; %! y2 = [0 0 1 1]; %! h = plot (x, interp1 (x1, y1, x), 'b', x1, y1, 'sb'); %! hold on %! g = plot (x, interp1 (x2, y2, x), 'r', x2, y2, '*r'); %! axis ([0.5 3.5 -0.5 1.5]); %! legend ([h(1), g(1)], {'left-continuous', 'right-continuous'}, ... %! 'location', 'northwest') %! legend boxoff %! %-------------------------------------------------------- %! % red curve is left-continuous and blue is right-continuous at x = 2 ##FIXME: add test for N-d arguments here ## For each type of interpolated test, confirm that the interpolated ## value at the knots match the values at the knots. Points away ## from the knots are requested, but only "nearest" and "linear" ## confirm they are the correct values. %!shared xp, yp, xi, style %! xp = 0:2:10; %! yp = sin (2*pi*xp/5); %! xi = [-1, 0, 2.2, 4, 6.6, 10, 11]; ## The following BLOCK/ENDBLOCK section is repeated for each style ## nearest, previous, next, linear, cubic, spline, pchip ## The test for ppval of cubic has looser tolerance, but otherwise ## the tests are identical. ## Note that the block checks style and *style; if you add more tests ## be sure to add them to both sections of each block. One test, ## style vs. *style, occurs only in the first section. ## There is an ENDBLOCKTEST after the final block %!test style = "nearest"; ## BLOCK %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!error interp1 (1,1,1, style) %!assert (interp1 (xp,[yp',yp'],xi,style), %! interp1 (xp,[yp',yp'],xi,["*",style]),100*eps) %!test style = ["*",style]; %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!assert (interp1 (yp, xi, style, 0), ... %! interp1 (1:numel (yp), yp, xi, style, 0), 10*eps) %!error interp1 (1,1,1, style) ## ENDBLOCK %!test style = "previous"; ## BLOCK %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) ## This test is expected to fail, so commented out. ## "previous" and "next" options are not symmetric w.r.t to flipping xp,yp #%!assert (interp1 (xp,yp,xi,style),... #%! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!error interp1 (1,1,1, style) %!assert (interp1 (xp,[yp',yp'],xi,style), %! interp1 (xp,[yp',yp'],xi,["*",style]),100*eps) %!test style = ["*",style]; %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) #%!assert (interp1 (xp,yp,xi,style),... #%! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!assert (interp1 (yp, xi, style, 0), ... %! interp1 (1:numel (yp), yp, xi, style, 0), 10*eps) %!error interp1 (1,1,1, style) ## ENDBLOCK %!test style = "next"; ## BLOCK %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) #%!assert (interp1 (xp,yp,xi,style),... #%! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!error interp1 (1,1,1, style) %!assert (interp1 (xp,[yp',yp'],xi,style), %! interp1 (xp,[yp',yp'],xi,["*",style]),100*eps) %!test style = ["*",style]; %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) #%!assert (interp1 (xp,yp,xi,style),... #%! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!assert (interp1 (yp, xi, style, 0), ... %! interp1 (1:numel (yp), yp, xi, style, 0), 10*eps) %!error interp1 (1,1,1, style) ## ENDBLOCK %!test style = "linear"; ## BLOCK %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!error interp1 (1,1,1, style) %!assert (interp1 (xp,[yp',yp'],xi,style), %! interp1 (xp,[yp',yp'],xi,["*",style]),100*eps) %!test style = ['*',style]; %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!assert (interp1 (yp, xi, style, 0), ... %! interp1 (1:numel (yp), yp, xi, style, 0), 10*eps) %!assert (interp1 ([1 2 2 3], [1 2 3 4], 2), 3) %!assert (interp1 ([3 2 2 1], [4 3 2 1], 2), 2) %!error interp1 (1,1,1, style) ## ENDBLOCK %!test style = "cubic"; ## BLOCK %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),100*eps) %!error interp1 (1,1,1, style) %!assert (interp1 (xp,[yp',yp'],xi,style), %! interp1 (xp,[yp',yp'],xi,["*",style]),100*eps) %!test style = ["*",style]; %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),100*eps) %!assert (interp1 (yp, xi, style, 0), ... %! interp1 (1:numel (yp), yp, xi, style, 0), 10*eps) %!error interp1 (1,1,1, style) ## ENDBLOCK %!test style = "pchip"; ## BLOCK %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!error interp1 (1,1,1, style) %!assert (interp1 (xp,[yp',yp'],xi,style), %! interp1 (xp,[yp',yp'],xi,["*",style]),100*eps) %!test style = ["*",style]; %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!assert (interp1 (yp, xi, style, 0), ... %! interp1 (1:numel (yp), yp, xi, style, 0), 10*eps) %!error interp1 (1,1,1, style) ## ENDBLOCK %!test style = "spline"; ## BLOCK %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!error interp1 (1,1,1, style) %!assert (interp1 (xp,[yp',yp'],xi,style), %! interp1 (xp,[yp',yp'],xi,["*",style]),100*eps) %!test style = ["*",style]; %!assert (interp1 (xp, yp, [min(xp)-1, max(xp)+1],style), [NA, NA]) %!assert (interp1 (xp,yp,xp,style), yp, 100*eps) %!assert (interp1 (xp,yp,xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp',style), yp', 100*eps) %!assert (interp1 (xp',yp',xp,style), yp, 100*eps) %!assert (isempty (interp1 (xp',yp',[],style))) %!assert (isempty (interp1 (xp,yp,[],style))) %!assert (interp1 (xp,[yp',yp'],xi(:),style),... %! [interp1(xp,yp,xi(:),style),interp1(xp,yp,xi(:),style)]) %!assert (interp1 (xp,yp,xi,style),... %! interp1 (fliplr (xp),fliplr (yp),xi,style),100*eps) %!assert (ppval (interp1 (xp,yp,style,"pp"),xi), %! interp1 (xp,yp,xi,style,"extrap"),10*eps) %!assert (interp1 (yp, xi, style, 0), ... %! interp1 (1:numel (yp), yp, xi, style, 0), 10*eps) %!error interp1 (1,1,1, style) ## ENDBLOCK ## ENDBLOCKTEST ## test extrapolation %!assert (interp1 ([1:5],[3:2:11],[0,6],"linear","extrap"), [1, 13], eps) %!assert (interp1 ([1:5],[3:2:11],[0,6],"nearest","extrap"), [3, 11], eps) %!assert (interp1 ([1:5],[3:2:11],[0,6],"previous","extrap"), [3, 11], eps) %!assert (interp1 ([1:5],[3:2:11],[0,6],"next","extrap"), [3, 11], eps) %!assert (interp1 (xp, yp, [-1, max(xp)+1],"linear",5), [5, 5]) %!assert (interp1 ([0,1],[1,0],[0.1,0.9;0.2,1.1]), [0.9 0.1; 0.8 NA], eps) %!assert (interp1 ([0,1],[1,0],[0.1,0.9;0.2,1]), [0.9 0.1; 0.8 0], eps) ## Basic sanity checks %!assert (interp1 (1:2,1:2,1.4,"nearest"), 1) %!assert (interp1 (1:2,1:2,1.6,"previous"), 1) %!assert (interp1 (1:2,1:2,1.4,"next"), 2) %!assert (interp1 (1:2,1:2,1.4,"linear"), 1.4) %!assert (interp1 (1:4,1:4,1.4,"cubic"), 1.4) %!assert (interp1 (1:2,1:2,1.1,"spline"), 1.1) %!assert (interp1 (1:3,1:3,1.4,"spline"), 1.4) %!assert (interp1 (1:2:4,1:2:4,1.4,"*nearest"), 1) %!assert (interp1 (1:2:4,1:2:4,2.2,"*previous"), 1) %!assert (interp1 (1:2:4,1:2:4,1.4,"*next"), 3) %!assert (interp1 (1:2:4,1:2:4,[0,1,1.4,3,4],"*linear"), [NA,1,1.4,3,NA]) %!assert (interp1 (1:2:8,1:2:8,1.4,"*cubic"), 1.4) %!assert (interp1 (1:2,1:2,1.3, "*spline"), 1.3) %!assert (interp1 (1:2:6,1:2:6,1.4,"*spline"), 1.4) %!assert (interp1 ([3,2,1],[3,2,2],2.5), 2.5) %!assert (interp1 ([4,4,3,2,0],[0,1,4,2,1],[1.5,4,4.5], "linear"), [1.75,1,NA]) %!assert (interp1 (0:4, 2.5), 1.5) ## Left and Right discontinuities %!assert (interp1 ([1,2,2,3,4],[0,1,4,2,1],[-1,1.5,2,2.5,3.5], "linear", "extrap", "right"), [-2,0.5,4,3,1.5]) %!assert (interp1 ([1,2,2,3,4],[0,1,4,2,1],[-1,1.5,2,2.5,3.5], "linear", "extrap", "left"), [-2,0.5,1,3,1.5]) ## Test input validation %!error <Invalid call> interp1 () %!error <Invalid call> interp1 (1) %!error <Invalid call> interp1 (1,2,3,4,5,6,7) %!error <minimum of 2 points required> interp1 (1,1,1, "linear") %!error <minimum of 2 points required> interp1 (1,1,1, "*nearest") %!error <minimum of 2 points required> interp1 (1,1,1, "*linear") %!error <minimum of 2 points required> interp1 (1,1,1, "previous") %!error <minimum of 2 points required> interp1 (1,1,1, "*previous") %!warning <multiple discontinuities> interp1 ([1 1 1 2], [1 2 3 4], 1); %!error <discontinuities not supported> interp1 ([1 1],[1 2],1, "next") %!error <discontinuities not supported> interp1 ([1 1],[1 2],1, "pchip") %!error <discontinuities not supported> interp1 ([1 1],[1 2],1, "cubic") %!error <discontinuities not supported> interp1 ([1 1],[1 2],1, "spline") %!error <invalid METHOD 'invalid'> interp1 (1:2,1:2,1, "invalid")