moving median with variable window

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Michal
Michal el 23 de Sept. de 2024
Comentada: Bruno Luong el 25 de Sept. de 2024
Is there any way how to effectively generalize movmedian function to work with variable window length or local variable k-point median values, where k is vector with the same length as length of input vector (lenght(x) = lenght(k))?
Example:
x = 1:6
k = 2,3,3,5,3,2
M = movmedian_vk(x,k)
M = 1, 2, 3, 4, 5, 5.5
My naive solution looks like:
function M = movmedian_vk(x,k)
if length(k) ~= length(x)
error('Incomaptible input data')
end
M = zeros(size(x));
[uk,~,ck] = unique(k);
for i = 1:length(uk)
M_i = movmedian(x,uk(i));
I_i = (ck == i);
M(I_i) = M_i(I_i);
end
end
  2 comentarios
Image Analyst
Image Analyst el 23 de Sept. de 2024
Can you explain the use case? Why do you want to do this?
Michal
Michal el 24 de Sept. de 2024
Editada: Michal el 24 de Sept. de 2024
Robust and effective trend extraction in a case of a priori known 1-D signal parts with high slope changes (typicaly by active control of dynamic system). Median filter then used short window in a case of active control and long windows in opposite case.
But after some additional test I learned that this naive approch is not suitable for reliable trend estimation.
Anyway, I will be very happy for any hint how to apply robust median filter on my use case, where separate parts of signal shoud be filtered with different filter windows (something like weighting).

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Respuestas (3)

Bruno Luong
Bruno Luong el 23 de Sept. de 2024
Editada: Bruno Luong el 23 de Sept. de 2024
Ran in:
One way (for k not very large)
x = 1:6
x = 1×6
1 2 3 4 5 6
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k = [2,3,4,5,3,2]; % Note: I change k(3) to 4
winmedian(x,k)
ans = 1×6
1.0000 2.0000 2.5000 4.0000 5.0000 5.5000
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function mx = winmedian(x,k)
x = reshape(x, 1, []);
k = reshape(k, 1, []);
K = max(k);
p = floor(K/2);
q = K-p;
qm1 = q-1;
r = [x(q:end), nan(1,qm1)];
c = [nan(1,p), x(1:q)];
X = hankel(c,r);
i = (-p:qm1).';
kb = floor(k/2);
kf = k-1-kb;
mask = i < -kb | i > kf;
X(mask) = NaN;
mx = median(X,1,'omitnan');
end
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Matt J
Matt J el 24 de Sept. de 2024
Editada: Matt J el 24 de Sept. de 2024
Ran in:
When there are a small number of unique k(i), yes, yours is best. However, more generally, Bruno's is faster:
k = randi(30,1,1e5);
x = rand(1,1e5);
timeit(@() winmedianMichal(x,k))
ans = 0.0579
timeit(@() winmedianBruno(x,k))
ans = 0.0371
function M = winmedianMichal(x,k)
if length(k) ~= length(x)
error('Incomaptible input data')
end
M = zeros(size(x));
[uk,~,ck] = unique(k);
for i = 1:length(uk)
M_i = movmedian(x,uk(i));
I_i = (ck == i);
M(I_i) = M_i(I_i);
end
end
function mx = winmedianBruno(x,k)
x = reshape(x, 1, []);
k = reshape(k, 1, []);
K = max(k);
p = floor(K/2);
q = K-p;
qm1 = q-1;
r = [x(q:end), nan(1,qm1)];
c = [nan(1,p), x(1:q)];
X = hankel(c,r);
i = (-p:qm1).';
kb = floor(k/2);
kf = k-1-kb;
mask = i < -kb | i > kf;
X(mask) = NaN;
mx = median(X,1,'omitnan');
end
Michal
Michal el 24 de Sept. de 2024
@Matt J Good point...

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Matt J
Matt J el 23 de Sept. de 2024
Editada: Matt J el 24 de Sept. de 2024
Ran in:
x = rand(1,6)
x = 1×6
0.1034 0.9884 0.6244 0.0233 0.2999 0.6556
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k = [2,3,3,5,3,2];
n=numel(x);
J=repelem(1:n,k);
I0=1:numel(J);
splitMean=@(vals,G) (accumarray(G(:),vals(:))./accumarray(G(:),ones(numel(vals),1)))';
cc=repelem( round(splitMean( I0,J )) ,k);
zz=min(max(I0-cc+J+1,1),n+2);
vals=[nan,x,nan];
vals=vals(zz);
I=I0-repelem( find(diff([0,J]))-1 ,k);
X=accumarray([I(:),J(:)], vals(:), [max(k),n],[],nan);
M = median(X,1,'omitnan')
M = 1×6
0.1034 0.6244 0.6244 0.6244 0.2999 0.4777
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Matt J
Matt J el 24 de Sept. de 2024
Editada: Matt J el 24 de Sept. de 2024
Ran in:
Anyway, I will be very happy for any hint how to apply robust median filter on my use case, where separate parts of signal shoud be filtered with different filter windows (something like weighting).
If your movmedian windows are simply varying over a small sequence of consecutive intervals, then the code below shows a little bit of speed-up. It won't give the exact same output near the break points between intervals, but it should be fairly close.
x = rand(1,1e5);
k = 8000*ones(1,1e5);
k(20000:30000) =50;
k(18000:20000) =200;
k(30000:32000) =200;
timeit(@() winmedianMichal(x,k))
ans = 0.0134
timeit(@() winmedianMatt(x,k))
ans = 0.0097
function M = winmedianMichal(x,k)
if length(k) ~= length(x)
error('Incomaptible input data')
end
M = zeros(size(x));
[uk,~,ck] = unique(k);
for i = 1:length(uk)
M_i = movmedian(x,uk(i));
I_i = (ck == i);
M(I_i) = M_i(I_i);
end
end
%Requires download of groupConsec
%https://www.mathworks.com/matlabcentral/fileexchange/78008-tools-for-processing-consecutive-repetitions-in-vectors
function M = winmedianMatt(x,k)
M=splitapply(@(a,b){movmedian(a,b(1))}, x,k, groupConsec(k));
M=[M{:}];
end
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Michal
Michal el 25 de Sept. de 2024
@Bruno Luong Could you add the reference on the Weiss paper?
Bruno Luong
Bruno Luong el 25 de Sept. de 2024
Done; somehow this Answers forum and firefox have issue when I edit it, must use another browser.

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