Efficient Weighted Moving average
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Matlab User
el 13 de Mzo. de 2017
I have a matrix with x, y, and an uncertainty value (25x3 double). I want to compute a moving average of these points weighted by the third value, (V(:,3)), with a time window of say 5 points. What is the most efficient way to achieve this?
2 comentarios
Respuesta aceptada
John BG
el 16 de Mzo. de 2017
Editada: John BG
el 16 de Mzo. de 2017
Hi Matlab User
1.
simulating data
clear all,clc
V=zeros(25,3);x=V(:,1);y=V(:,2);
w=randi([1 9],25,1);
w=w/sum(w);V(:,3)=w
V(:,1)=randi([-10 10],25,1) % x
V(:,2)=randi([-10 10],25,1) % y
V(:,3)=w;
.
the data
format short
V =
-3.0000 3.0000 0.0857
-5.0000 8.0000 0.0190
-10.0000 3.0000 0.0476
-2.0000 -1.0000 0.0476
4.0000 1.0000 0.0571
0 3.0000 0.0190
1.0000 -7.0000 0.0190
10.0000 -1.0000 0.0857
10.0000 -1.0000 0.0762
-6.0000 -3.0000 0.0762
-5.0000 -9.0000 0.0381
0 4.0000 0.0095
-7.0000 1.0000 0.0190
-8.0000 -10.0000 0.0286
3.0000 8.0000 0.0381
-4.0000 -4.0000 0.0095
2.0000 6.0000 0.0190
-9.0000 0 0.0095
5.0000 6.0000 0.0286
-4.0000 -2.0000 0.0286
-10.0000 6.0000 0.0667
-9.0000 -2.0000 0.0381
-9.0000 1.0000 0.0095
7.0000 4.0000 0.0476
9.0000 -6.0000 0.0762
2.
averaging with the shifting window and applying the weight V(:,:,3)
N=25
R=zeros(N,1)
for k=3:1:N-2
s=[k-2 k-1 k k+1 k+2]
R(k)= mean(.5*(V(s,2)+V(s,1)).*V(s,3))
end
R =
0
0
-0.0133
-0.0076
-0.0248
0.0857
0.1686
0.0714
0.0124
0.0276
-0.0610
-0.1810
-0.0705
-0.0248
-0.0133
-0.0105
0.0724
0.0133
-0.0057
-0.0629
-0.0619
-0.0410
-0.0010
0
0
This does not apply the shifting window on the first 2 and last 2 sames, there aren't 5 samples to apply the window on head and tail anyway, aren't they?
if you find this answer useful would you please be so kind to mark my answer as Accepted Answer?
To any other reader, please if you find this answer
please click on the thumbs-up vote link
thanks in advance
John BG
9 comentarios
dpb
el 20 de Mzo. de 2017
Editada: dpb
el 21 de Mzo. de 2017
However is fine... :) I've noticed quite a few have typed 'dpd' rather than the trailing 'b'; I'm not sure why. I kinda' like the geometry of lower case string however as being mirror image/rotations of a single basic form...
"Addendum. An addendum, in general, is an addition required to be made to a document by its author subsequent to its printing or publication. It comes from the Latin verbal phrase addendum est, being the gerundive form of the verb addo, addere, addidi, additum, "to give to, add to", meaning "(that which) must be added"."
Más respuestas (2)
dpb
el 13 de Mzo. de 2017
Editada: dpb
el 17 de Mzo. de 2017
N=5;
yavN=conv(v(:,2).*v(:,3),ones(1,N)/N,'valid');
discarding the zero-padded end values. See
doc conv % for other options, details...
ADDENDUM
If not clear how to use mean in the above, simply compute it "on the fly" as well instead of using just a single column from V...note the use of the optional DIM second argument to the MEAN function...
C=conv(mean(V(:,1:2),2).*V(:,3),ones(1,N)/N,'valid');
1 comentario
Jan
el 20 de Mzo. de 2017
Editada: Jan
el 20 de Mzo. de 2017
Some further speed measurements:
function speedtest
N = 10000;
tic; for k = 1:N; R = test1(V); end, toc
tic; for k = 1:N; R = test2(V); end, toc
tic; for k = 1:N; R = test3(V); end, toc
tic; for k = 1:N; R = test4(V); end, toc
function R = test1(V) % John BG
N=size(V, 1);
R=zeros(N,1);
for k=3:1:N-2
s=[k-2 k-1 k k+1 k+2];
R(k)= mean(.5*(V(s,2)+V(s,1)).*V(s,3));
end
function R = test2(V) % Jan
% 1. repeated calcultations moved outside the loop
% 2. Indexing by a:b is much faster than using a pre-calculated vector
N = size(V, 1);
R = zeros(N,1);
X = 0.5 * sum(V(:, 1:2), 2) .* V(:, 3);
for k = 3:1:N-2
R(k) = sum(X(k-2:k+2)) * 0.2;
end
function R = test3(V) % dpb
N = 5;
R = conv(mean(V(:,1:2), 2) .* V(:,3), ones(1,N) / N,'valid');
function R = test4(V) % dpb without MEAN()
N = 5;
R = conv(0.5 * (V(:,1) + V(:, 2)) .* V(:,3), ones(1,N) / N, 'valid');
Results (R2016b/64, Core2Duo):
Elapsed time is 3.138929 seconds. John BG
Elapsed time is 0.444694 seconds. Improved loop
Elapsed time is 0.193468 seconds. dpb
Elapsed time is 0.119400 seconds. dpb without MEAN()
What happens, if the input is not tiny:
V = rand(25000, 3);
N = 10;
Elapsed time is 3.667920 seconds.
Elapsed time is 0.418300 seconds.
Elapsed time is 0.018349 seconds.
Elapsed time is 0.014222 seconds.
Conclusion: Loops profit from smart indexing and avoiding repeated calculations, but conv rules. mean has a remarkable overhead.
2 comentarios
dpb
el 20 de Mzo. de 2017
Editada: dpb
el 21 de Mzo. de 2017
"...mean has a remarkable overhead."_
Interesting, wonder why so much. Well, let's see...
C:\ML_R2014b\toolbox\matlab\datafun\mean.m
>> edit mean
Huh. It's not a builtin that I'd just presumed would be given the ubiquitousness of the operation. Has lots of input checking as well before finally getting around to doing any work.
Have to remember that when speed is of essence (altho since I've given up the consulting gig for the farm, that's not likely to ever be so for me again, but for others...)
ADDENDUM
Wonder how much penalty there would be in
sum(V(:,1:2),2)/2
in comparison as replacement syntax for explicit sum (I hate having to write V twice't when subscripting can be used but that's just me, granted)...
Jan
el 21 de Mzo. de 2017
Editada: Jan
el 21 de Mzo. de 2017
x = rand(1000, 2);
tic; for k = 1:100000; m = x(:, 1) + x(:, 2); end; toc
tic; for k = 1:100000; m = sum(x, 2); end; toc
Elapsed time is 0.120969 seconds.
Elapsed time is 0.156458 seconds.
The difference can be measured. SUM is parallelized for more than 88999 elements. Then the number of cores matter also.
x = rand(100000, 2);
tic; for k = 1:1000; m = x(:, 1) + x(:, 2); end; toc
tic; for k = 1:1000; m = sum(x, 2); end; toc
Elapsed time is 0.103634 seconds.
Elapsed time is 0.148599 seconds.
But rmember, we are talking about 0.00004 seconds. "sum(x,2)" can save minute of hourse during the debugging. Therefore I prefer sum and apply the dirty tricks like v(:,1)+v(:,2) only for bottlenecks and with an exhaustive documentation and a unit-test function, which specifically cares about these lines.
Ver también
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