I would like to contribute to this thread an algorithm that I have developed myself:

This algorithm signals when the data points are a specified number of standard deviations away from the moving mean. However, when a signal is detected, subsequent data points that are also a signal (so significantly away from the moving mean), will not corrupt the signal threshold. That is, the algorithm creates a '*new mean*' and '*new st.dev.*' in which the data points that are signals are *not* used. Therefore, the threshold remains uncorrupted and is able to correctly identify future signals too, without loss of performance. This works extremely well!

In order to display the power of this robust algorithm, I have prepared a demo in which the user can specify its own data. This little demo displays both how the algorithm works and why it is so useful.

**The full working Matlab code for this demo**:

```
function [] = RobustDetectionDemo()
%% SPECIFICATIONS
LAG = 10; % lag for the moving mean and moving st. dev.
DIFF = 3.5; % number of st. dev. from the mean to signal
INFLUENCE = 0.0; % when signal: how much is mean/st.dev. influenced?
% or e.g. 0.05/0.1 for influencing
DIRECTION = 'both'; % signal when 'up'/'down'/'both' from the mean
%%
figure(1);
subplot(2,2,1);
title('Draw 30 data points');
ylim([0 5]); xlim([0 50]);
[x,y] = ginputExtra_realtime(30, true, LAG, DIFF, INFLUENCE, DIRECTION);
end
function [x y] = ginputExtra_realtime(n,booText, LAG, DIFF, INFLUENCE, DIRECTION)
if booText == true
bText = booText;
else
bText = false;
end
H = gca;
set(H, 'YLimMode', 'manual'); set(H, 'XLimMode', 'manual');
set(H, 'YLim', get(H,'YLim')); set(H, 'XLim', get(H,'XLim'));
numPoints = n; xg = []; yg = [];
for i=1:numPoints
[xi yi] = ginput(1);
xg = [xg xi]; yg = [yg yi];
if i == 1
hold on;
plot(H, xg(i),yg(i),'ro');
if bText text(xg(i),yg(i),num2str(i),'FontSize',12); end
else
plot(xg([i-1:i]),yg([i-1:i]),'r');
if bText text(xg(i),yg(i),num2str(i),'FontSize',12); end
if length(xg) > LAG
robustMA(xg, yg, LAG, DIFF, INFLUENCE, DIRECTION);
end
end
end
hold off;
x = xg; y = yg;
end
function [] = robustMA( x, y, lag, diff, influence, direction)
% robustMA :: Signal detection algorithm ::
% Author: Jean-Paul van Brakel
% ************************************************************ %
% TO BE USED FOR: *determining significant and sudden changes*
% ************************************************************ %
% x = x-axis data
% y = y-axis data
% lag = lag of moving mean and moving st.dev.
% diff = number of st.dev. away from the mean in order to give a signal
% influence = number between 0 and 1 that indicates influence of signals
% direction = 'up'/'down'/'both' which means the following:
% - 'up' : only signal for deviations ABOVE the mean
% - 'down': only signal for deviations BELOW the mean
% - 'both': signal for deviations ABOVE and BELOW the mean
p = y;
outputmean = tsmovavg(y,'s',lag,2);
outputstdev = movingstd(y,lag,'backward');
newMean = zeros(1, length(outputmean));
newStdev = zeros(1, length(outputmean));
signals = ones(1, length(outputmean));
newMean(lag-1) = outputmean(lag);
newStdev(lag-1) = outputstdev(lag);
for i = lag:length(outputmean)
if strcmp(direction, 'up')
if (p(i) > newMean(i-1)+diff*newStdev(i-1))
newMean(i) = (newMean(i-1) + influence*p(i))/(1+influence);
newStdev(i) = (newStdev(i-1) + influence*sqrt((p(i)-newMean(i-1))^2))/(1+influence);
signals(i) = 2;
else
newMean(i) = (newMean(i-1)+p(i))/2;
newStdev(i) = (newStdev(i-1) + sqrt((p(i)-newMean(i-1))^2))/2;
signals(i) = 1;
end
elseif strcmp(direction, 'down')
if (p(i) < newMean(i-1)-diff*newStdev(i-1))
newMean(i) = (newMean(i-1) + influence*p(i))/(1+influence);
newStdev(i) = (newStdev(i-1) + influence*sqrt((p(i)-newMean(i-1))^2))/(1+influence);
signals(i) = 2;
else
newMean(i) = (newMean(i-1)+p(i))/2;
newStdev(i) = (newStdev(i-1) + sqrt((p(i)-newMean(i-1))^2))/2;
signals(i) = 1;
end
elseif strcmp(direction, 'both')
if (p(i) > newMean(i-1)+diff*newStdev(i-1) || ...
p(i) < newMean(i-1)-diff*newStdev(i-1))
newMean(i) = (newMean(i-1) + influence*p(i))/(1+influence);
newStdev(i) = (newStdev(i-1) + influence*sqrt((p(i)-newMean(i-1))^2))/(1+influence);
signals(i) = 2;
else
newMean(i) = (newMean(i-1)+p(i))/2;
newStdev(i) = (newStdev(i-1) + sqrt((p(i)-newMean(i-1))^2))/2;
signals(i) = 1;
end
end
end
figure(1);
subplot(2,2,2);
hold on;
title('Algorithm output');
area(x, newMean+diff*newStdev, 'FaceColor', [0.9 0.9 0.9], 'EdgeColor', 'none');
area(x, newMean, 'FaceColor', [1 1 1], 'EdgeColor', 'none');
area(x, newMean, 'FaceColor', [0.9 0.9 0.9], 'EdgeColor', 'none');
area(x, newMean-diff*newStdev, 'FaceColor', [1 1 1], 'EdgeColor', 'none');
plot(x, p, ':r', 'LineWidth', 1, 'Color', 'black');
plot(x, newMean, 'LineWidth', 2, 'Color', 'red');
plot(x, newMean+newStdev, 'LineWidth', 2, 'Color', 'green');
plot(x, newMean-newStdev, 'LineWidth', 2, 'Color', 'green');
xlim([0 50]); ylim([0 5])
hold off;
subplot(2,2,4);
hold on;
title('Signal output');
stairs(x, signals, 'LineWidth', 2, 'Color', 'blue');
ylim([0 3]); xlim([0 50]);
hold off;
end
function s = movingstd(x,k,windowmode)
% movingstd: efficient windowed standard deviation of a time series
% usage: s = movingstd(x,k,windowmode)
%
% Movingstd uses filter to compute the standard deviation, using
% the trick of std = sqrt((sum(x.^2) - n*xbar.^2)/(n-1)).
% Beware that this formula can suffer from numerical problems for
% data which is large in magnitude.
% check for a windowmode
if (nargin<3) || isempty(windowmode)
% supply the default:
windowmode = 'central';
elseif ~ischar(windowmode)
error 'If supplied, windowmode must be a character flag.'
end
% check for a valid shortening.
valid = {'central' 'forward' 'backward'};
windowmode = lower(windowmode);
ind = strmatch(windowmode,valid);
if isempty(ind)
error 'Windowmode must be a character flag: ''c'', ''b'', or ''f''.'
else
windowmode = valid{ind};
end
% length of the time series
n = length(x);
% check for valid k
if (nargin<2) || isempty(k) || (rem(k,1)~=0)
error 'k was not provided or not an integer.'
end
switch windowmode
case 'central'
if k<1
error 'k must be at least 1 for windowmode = ''central''.'
end
if n<(2*k+1)
error 'k is too large for this short of a series and this windowmode.'
end
otherwise
if k<2
error 'k must be at least 2 for windowmode = ''forward'' or ''backward''.'
end
if (n<k)
error 'k is too large for this short of a series.'
end
end
% Improve the numerical analysis by subtracting off the series mean
% this has no effect on the standard deviation.
x = x - mean(x);
% we will need the squared elements
x2 = x.^2;
% split into the three windowmode cases for simplicity
A = 1;
switch windowmode
case 'central'
B = ones(1,2*k+1);
s = sqrt((filter(B,A,x2) - (filter(B,A,x).^2)*(1/(2*k+1)))/(2*k));
s(k:(n-k)) = s((2*k):end);
case 'forward'
B = ones(1,k);
s = sqrt((filter(B,A,x2) - (filter(B,A,x).^2)*(1/k))/(k-1));
s(1:(n-k+1)) = s(k:end);
case 'backward'
B = ones(1,k);
s = sqrt((filter(B,A,x2) - (filter(B,A,x).^2)*(1/k))/(k-1));
end
% special case the ends as appropriate
switch windowmode
case 'central'
% repairs are needed at both ends
for i = 1:k
s(i) = std(x(1:(k+i)));
s(n-k+i) = std(x((n-2*k+i):n));
end
case 'forward'
% the last k elements must be repaired
for i = (k-1):-1:1
s(n-i+1) = std(x((n-i+1):n));
end
case 'backward'
% the first k elements must be repaired
for i = 1:(k-1)
s(i) = std(x(1:i));
end
end
end
```

The necessary parameters are:

`LAG`

: lag for the moving mean and moving st. dev.
`DIFF`

: number of st. dev. away from the mean to generate a signal
`INFLUENCE`

: when there is a signal, how much is mean/st.dev. influenced? (number between 0-1)
`DIRECTION`

: signal when deviation is 'up'/'down'/'both' away from the mean?

As you can see, I used the settings `LAG=10; DIFF=3.5; INFLUENCE=0;`

for this demo. Feel free to fiddle around with these parameters and study the differences in performance of the algorithm.