# average number of different values ​​in a column

I had a question in Matlab. It is so, I try to take average of the different number of values ​​in a column. For example, if we have the column below,

X = [1 1 2 3 4 3 8 2 1 3 5 6 7 7 5]

first I want to start by taking the average of 5 values ​​and plot them. In the case above, I should receive three averages that I could plot. Then take 10 values ​​at a time and so on. I wonder if you have to write custom code to fix it. So I was wondering if anyone could help me with it.

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X: looks like a row, but that is a coulmn! – Fredrik Hansson Jun 17 '13 at 10:42
If it's 1-dimensional, that doesn't matter much. – Stewie Griffin Jun 17 '13 at 12:15

The fastest way is probably to rearrange your initial vector X into some matrix, with each column storing the required values to average:

A = reshape(X, N, []);

where N is the desired number of rows in the new matrix, and the empty brackets ([]) tell MATLAB to calculate the number of columns automatically. Then you can average each column using mean:

X_avg = mean(A);

Vector X_avg stores the result. This can be done in one line like so:

X_avg = mean(reshape(X, N, []));

Note that the number of elements in X has to be divisible by N, otherwise you'll have to either pad it first (e.g with zeroes), or handle the "leftover" tail elements separately:

tail = mod(numel(X), N);
X_avg = mean(reshape(X(1:numel(X) - tail), N, [])); %// Compute average values
X_avg(end + 1) = mean(X(end - tail + 1:end));       %// Handle leftover elements

Later on you can put this code in a loop, computing and plotting the average values for a different value of N in each iteration.

### Example #1

X = [1 1 2 3 4 3 8 2 1 3 5 6 7 7 5];
N = 5;

tail = mod(numel(X), N);
X_avg = mean(reshape(X(1:numel(X) - tail), N, []))
X_avg(end + 1) = mean(X(end - tail + 1:end))

The result is:

X_avg =
2.2000   3.4000   6.0000

### Example #2

Here's another example (this time the length of X is not divisible by N):

X = [1 1 2 3 4 3 8 2 1 3 5 6 7 7 5];
N = 10;

tail = mod(numel(X), N);
X_avg = mean(reshape(X(1:numel(X) - tail), N, []))
X_avg(end + 1) = mean(X(end - tail + 1:end))

The result is:

X_avg =
2.8000   6.0000
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+1, nice solution. I'm not completely sure what OP wants, but I guess it would make more sense to not include the zeros in the last column when calculating the mean... – Stewie Griffin Jun 17 '13 at 13:14
Thanks to all of you, your help was very good. Thanks – Fredrik Hansson Jun 17 '13 at 13:21
@RobertP. That would be problematic if the number of elements in X is not a multiple of N. However, if the OP wishes not to include the padded zeroes in the computation, the last average value can be recalculated separately with mean(X(end - mod(numel(X), N) + 1:end)) – Eitan T Jun 17 '13 at 13:22
@EitanT: I know that would be problematic using reshape, that's why I didn't propose a solution =P – Stewie Griffin Jun 17 '13 at 13:24
@RobertP. Looks fine, except that it requires the Statistics Toolbox :) – Eitan T Jun 18 '13 at 7:51

This should do the trick:

For a selected N (the number of values you want to take the average of):

N = 5;
mean_vals = arrayfun(@(n) mean(X(n-1+(1:N))),1:N:length(X))

Note: This does not check if Index exceeds matrix dimensions.

If you want to skip the last numbers, this should work:

mean_vals = arrayfun(@(n) mean(X(n-1+(1:N))),1:N:(length(X)-mod(length(X),N)));

if mod(length(X),N) ~= 0
mean_vals(end+1) = mean(X(numel(X)+1-mod(length(X),N):end))
end

UPDATE: This is a modification of Eitan's first answer (before it was edited). It uses nanmean(), which takes the mean of all values that are not NaN. So, instead of filling the remaining rows with zeros, fill them with NaN, and just take the mean.

X = [X(:); NaN(mod(N - numel(X), N), 1)];
X_avg = nanmean(reshape(X, N, []));
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Thanks for your quick reply. I ran your code but got the problem that you said I could get, Index Exceeds matrix dimensions. Error in @ (n) mean (X (n-1 + (1: N))) I tried with other values ​​such as 2, and it worked. My column contains 390 values. I want to use N = 10, N = 20, N = 30 and N = 50. So my question is if it could be fixed for the N that I mentioned? – Fredrik Hansson Jun 17 '13 at 12:42
It could be fixed, yes. But it depends on whatyou want to do when the condition: mod(length(X),N) == 0; is not met (which is the case for N=20 and N = 50). Do you want to skip the last 40 numbers? Suppose you want N=3, and take the mean of X = [1 2 3 4]. What do you plan to do with the 4? – Stewie Griffin Jun 17 '13 at 12:46
If I understand correctly, so I can skip the values ​​that cause the problem, so that N = 10, 20, 30, 50 functions. – Fredrik Hansson Jun 17 '13 at 12:54
I'm not sure what you're trying to say. Do you want to skip the last numbers? (That would be the number 4 in my previous comment), or do you want to skip the N that causes the problem? That would be N=3 in my comment? In your case, only N=10, and N=30 works. – Stewie Griffin Jun 17 '13 at 12:56
ok, only 10 and 30 works. I tried to say that i want to skip the values that couse the problem, or just take an average of the values ​​that remains, N does not affect anymore then. – Fredrik Hansson Jun 17 '13 at 13:00

It would be helpful if you posted some code and point out exactly what is not working.

As a first pointer. If

X = [1 1 2 3 4 3 8 2 1 3 5 6 7 7 5]

the three means in blocks of 5 you are interested in are

mean(X(1:5))
mean(X(6:10))
mean(X(11:15))

You will have to come up with a for loop or maybe some other way to iterate through the indices.

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I think you want something like this (I didn't use Matlab in a while, I hope the syntax is right):

X = [1 1 2 3 4 3 8 2 1 3 5 6 7 7 5],
currentAmount=5,
block=0,
while(numel(X)<=currentAmount)
while(numel(X)<=currentAmount+block*currentAmount)
mean(X(block*currentAmount+1:block*currentAmount+currentAmount));
block =block+1;
end;
currentAmount = currentAmount+5;
block=0;
end

This code will first loop through all elements calculating means of 5 elements at a time. Then, it will expand to 10 elements. Then to 15, and so on, until the number of elements from which you want to make the mean is bigger than the number of elements in the column.

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You need to store the mean value in a variable. In your case that would need to be a cell or struct, since it will be of varying length (dependent on currentAmount). – Stewie Griffin Jun 17 '13 at 12:00
@RobertP. Thank's for the input, from the question I thought he may just want to plot the variables. – simpleBob Jun 17 '13 at 12:36

If you are looking to average K random samples in your N-dimensional vector, then you could use:

N = length(X);
K = 20;    % or 10, or 30, or any integer less than or equal to N
indices = randperm(N, K);    % gives you K random indices from the range 1:N
result = mean(X(indices));   % averages the values of X at the K random
% indices from above

A slightly more compact form would be:

K = 20;
result = mean(X(randperm(length(X), K)));

If you are just looking to take every K consecutive samples from the list and average them then I am sure one of the previous answers will give you what you want.

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If you need to do this operation a lot, it might be worth writing your own function for it. I would recommend using @EitanT's basic idea: pad the data, reshape, take mean of each column. However, rather than including the zero-padded numbers at the end, I recommend taking the average of the "straggling" data points separately:

function m = meanOfN(x, N)
% function m = meanOfN(x, N)
% create groups of N elements of vector x
% and return their mean
% if numel(x) is not a multiple of N, the last value returned
% will be for fewer than N elements
Nf = N * floor( numel( x ) / N ); % largest multiple of N <= length of x
xr = reshape( x( 1:Nf ), N, []);
m = mean(xr);
if Nf < N
m = [m mean( x( Nf + 1:end ) )];
end

This function will return exactly what you were asking for: in the case of a 15 element vector with N=5, it returns 3 values. When the size of the input vector is not a multiple of N, the last value returned will be the "mean of what is left".

Often when you need to take the mean of a set of numbers, it is the "running average" that is of interest. So rather than getting [mean(x(1:5)) mean(x(6:10)) mean(11:15))], you might want

m(1) = mean(x(1:N));
m(2) = mean(x(2:N+1));
m(3) = mean(x(3:N+2));
...etc

That could be achieved using a simple convolution of your data with a vector of ones; for completeness, here is a possible way of coding that:

function m = meansOfN(x, n)
% function m = meansOfN(x, n)
% taking the running mean of the values in x
% over n samples. Returns a row vector of size (sizeof(x) - n + 1)
% if numel(x) < n, this returns an empty matrix
mv = ones(N,1) / N; % vector of ones, normalized
m = convn(x(:), mv, 'valid'); % perform 1D convolution

With these two functions in your path (save them in a file called meanOfN.m and meansOfN.m respectively), you can do anything you want. In any program you will be able to write

myMeans = meanOfN(1:30, 5);
myMeans2 = meansOfN(1:30, 6);

etc. Matlab will find the function, perform the calculation, return the result. Writing your custom functions for specific operations like this can be very helpful - not only does it keep your code clean, but you only have to test the function once...

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