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allan_modified.m
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function [retval, s, errorb, tau] = allan_modified(data,tau,name,verbose) % ALLAN_MODIFIED Compute the modified Allan deviation for a set of % time-domain frequency data % [RETVAL, S, ERRORB, TAU] = ALLAN_MODIFIED(DATA,TAU,NAME,VERBOSE) % % Inputs: % DATA should be a struct and have the following fields: % DATA.freq or DATA.phase |
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% A vector of fractional frequency measurements (df/f) in % DATA.freq *or* phase offset data (seconds) in DATA.phase % If phase data is not present, it will be generated by % integrating the fractional frequency data. % If both fields are present, then DATA.phase will be used. |
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% % DATA.rate or DATA.time |
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% The sampling rate in Hertz (DATA.rate) or a vector of % timestamps for each measurement in seconds (DATA.time). % DATA.rate is used if both fields are present. % If DATA.rate == 0, then the timestamps are used. |
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% % TAU is an array of tau values for computing Allan deviation. |
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% TAU values must be divisible by 1/DATA.rate (data points cannot be % grouped in fractional quantities!). Invalid values are ignored. |
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% NAME is an optional label that is added to the plot titles. % VERBOSE sets the level of status messages: |
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% 0 = silent & no data plots; 1 = status messages; 2 = all messages |
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% % Outputs: % RETVAL is the array of modified Allan deviation values at each TAU. % S is an optional output of other statistical measures of the data (mean, std, etc). % ERRORB is an optional output containing the error estimates for a % 1-sigma confidence interval. These values are shown on the figure for each point. % TAU is an optional output containing the array of tau values used in the % calculation (which may be a truncated subset of the input or default values). % % Example: % % To compute the modified Allan deviation for the data in the variable "lt": % >> lt % lt = |
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% freq: [1x86400 double] % rate: 0.5 |
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% % Use: % % >> adm = allan_modified(lt,[2 10 100],'lt data',1); % % The modified Allan deviation will be computed and plotted at tau = 2,10,100 seconds. % 1-sigma confidence intervals will be indicated by vertical lines at each point. % You can also use the default settings, which are usually a good starting point: % % >> adm = allan_modified(lt); % % % Notes: % This function calculates the modifed Allan deviation (MDEV). % The calculation is performed using phase data. If only frequency data is % provided, phase data is generated by integrating the frequency data. % No pre-processing of the data is performed. % For rate-based data, MDEV is computed only for tau values greater than the % minimum time between samples and less than the half the total time. For % time-stamped data, only tau values greater than the maximum gap between % samples and less than half the total time are used. % The calculation for fixed sample rate data is *much* faster than for % time-stamp data. You may wish to run the rate-based calculation first, % then compare with time-stamp-based. Often the differences are insignificant. % When phase data is generated by integrating time-stamped frequency data, % the final data point is dropped, because there is no timestamp for it. % This will create a [usually small] difference between the results from % analyzing the same data set with timestamp data and analyzing with a % fixed sample rate. See note in the code near line 350. % You can choose between loglog and semilog plotting of results by % commenting in/out the appropriate line. Search for "#PLOTLOG". % This function has been validated using the test data from NBS Monograph % 140, the 1000-point test data set given by Riley [1], and the example data % given in IEEE standard 1139-1999, Annex C. % The author welcomes other validation results, see contact info below. % % For more information, see: % [1] W. J. Riley, "The Calculation of Time Domain Frequency Stability," % Available on the web: % http://www.ieee-uffc.org/frequency_control/teaching.asp?name=paper1ht % % % M.A. Hopcroft |
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% mhopeng at gmail dot com |
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% % I welcome your comments and feedback! % % MH Mar2014 % v1.24 fix bug related to generating freq data from phase with timestamps |
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% (thanks to S. David-Grignot for finding the bug) |
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% MH Oct2010 % v1.22 tau truncation to integer groups; tau sort |
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% plotting bugfix |
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% v1.20 update to match allan.m (dsplot.m, columns) |
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% discard tau values with timestamp irregularities |
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% versionstr = 'allan_modified v1.24'; % MH MAR2010 % v1.1 bugfixes for irregular sample rates |
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% update consistency check |
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% % MH FEB2010 % v1.0 based on allan_overlap v2.0 % %#ok<*AGROW> % defaults if nargin < 4, verbose = 2; end if nargin < 3, name=''; end if nargin < 2 || isempty(tau), tau=2.^(-10:10); end if isfield(data,'rate') && isempty(data.rate), data.rate=0; end % v1.1 % Formatting for plots FontName = 'Arial'; FontSize = 14; plotlinewidth=2; if verbose >= 1, fprintf(1,'allan_modified: %s ',versionstr); end %% Data consistency checks if ~(isfield(data,'phase') || isfield(data,'freq')) |
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error('Either ''phase'' or ''freq'' must be present in DATA. See help file for details. [con0]'); |
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end if isfield(data,'time') |
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if isfield(data,'phase') && (length(data.phase) ~= length(data.time)) if isfield(data,'freq') && (length(data.freq) ~= length(data.time)) error('The time and freq vectors are not the same length. See help for details. [con2]'); else error('The time and phase vectors are not the same length. See help for details. [con1]'); end end if isfield(data,'phase') && (any(isnan(data.phase)) || any(isinf(data.phase))) error('The phase vector contains invalid elements (NaN/Inf). [con3]'); end if isfield(data,'freq') && (any(isnan(data.freq)) || any(isinf(data.freq))) error('The freq vector contains invalid elements (NaN/Inf). [con4]'); end if isfield(data,'time') && (any(isnan(data.time)) || any(isinf(data.time))) error('The time vector contains invalid elements (NaN/Inf). [con5]'); end |
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end % sort tau vector tau=sort(tau); %% Basic statistical tests on the data set if ~isfield(data,'freq') |
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if isfield(data,'rate') && data.rate ~= 0 data.freq=diff(data.phase).*data.rate; elseif isfield(data,'time') data.freq=diff(data.phase)./diff(data.time); end if verbose >= 1, fprintf(1,'allan_modified: Fractional frequency data generated from phase data (M=%g). ',length(data.freq)); end |
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end if size(data.freq,2) > size(data.freq,1), data.freq=data.freq'; end % ensure columns s.numpoints=length(data.freq); s.max=max(data.freq); s.min=min(data.freq); s.mean=mean(data.freq); s.median=median(data.freq); if isfield(data,'time') |
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if size(data.time,2) > size(data.time,1), data.time=data.time'; end % ensure columns s.linear=polyfit(data.time(1:length(data.freq)),data.freq,1); |
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elseif isfield(data,'rate') && data.rate ~= 0; |
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s.linear=polyfit((1/data.rate:1/data.rate:length(data.freq)/data.rate)',data.freq,1); |
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error('Either "time" or "rate" must be present in DATA. Type "help allan_modified" for details. [err1]'); |
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end s.std=std(data.freq); if verbose >= 2 |
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fprintf(1,'allan_modified: fractional frequency data statistics: '); disp(s); |
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end % scale to median for plotting medianfreq=data.freq-s.median; sm=[]; sme=[]; % Screen for outliers using 5x Median Absolute Deviation (MAD) criteria MAD = median(abs(medianfreq)/0.6745); if verbose >= 1 && any(abs(medianfreq) > 5*MAD) |
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fprintf(1, 'allan_modified: NOTE: There appear to be outliers in the frequency data. See plot. '); |
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end %%%% % There are two cases, either using timestamps or rate: %% Fixed Sample Rate Data % If there is a regular interval between measurements, calculation is much % easier/faster if isfield(data,'rate') && data.rate > 0 % if data rate was given |
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if verbose >= 1 fprintf(1, 'allan_modified: regular data '); if isfield(data,'freq') fprintf(1, '(%g freq data points @ %g Hz) ',length(data.freq),data.rate); elseif isfield(data,'phase') fprintf(1, '(%g phase data points @ %g Hz) ',length(data.phase),data.rate); else error(' phase or freq data missing [err10]'); end end % string for plot title name=[name ' (' num2str(data.rate) ' Hz)']; % what is the time interval between data points? tmstep = 1/data.rate; % Is there time data? Just for curiosity/plotting, does not impact calculation if isfield(data,'time') % adjust time data to remove any starting gap; first time step % should not be zero for comparison with freq data dtime=data.time-data.time(1)+mean(diff(data.time)); dtime=dtime(1:length(medianfreq)); % equalize the data vector lengths for plotting (v1.1) if verbose >= 2 fprintf(1,'allan_modified: End of timestamp data: %g sec. ',dtime(end)); if (data.rate - 1/mean(diff(dtime))) > 1e-6 fprintf(1,'allan_modified: NOTE: data.rate (%f Hz) does not match average timestamped sample rate (%f Hz) ',data.rate,1/mean(diff(dtime))); end end else % create time axis data using rate (for plotting only) dtime=(tmstep:tmstep:length(data.freq)*tmstep); end % is phase data present? If not, generate it if ~isfield(data,'phase') nfreq=data.freq-s.mean; dphase=zeros(1,length(nfreq)+1); dphase(2:end) = cumsum(nfreq).*tmstep; if verbose >= 1, fprintf(1,'allan_modified: phase data generated from fractional frequency data (N=%g). ',length(dphase)); end else dphase=data.phase; end % check the range of tau values and truncate if necessary % find halfway point of time record halftime = round(tmstep*length(data.freq)/2); % truncate tau to appropriate values tau = tau(tau >= tmstep & tau <= halftime); if verbose >= 2, fprintf(1, 'allan_modified: allowable tau range: %g to %g sec. (1/rate to total_time/2) ',tmstep,halftime); end |
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% find the number of data points in each tau group % number of samples N=length(dphase); m = data.rate.*tau; % only integer values allowed (no fractional groups of points) %tau = tau(m-round(m)<1e-8); % numerical precision issues (v1.1) tau = tau(m==round(m)); % The round() test is only correct for values < 2^53 %m = m(m-round(m)<1e-8); % change to round(m) for integer test v1.22 m = m(m==round(m)); %m=round(m); if verbose >= 1, fprintf(1,'allan_modified: calculating modified Allan deviation... '); end % calculate the modified Allan deviation for each value of tau k=0; tic; for i = tau k=k+1; pa=[]; if verbose >= 2, fprintf(1,'%d ',i); end mphase = dphase; % calculate overlapping "phase averages" (x_k) for p=1:m(k) % truncate frequency set length to an even multiple of this tau value mphase=mphase(1:end-rem(length(mphase),m(k))); % group phase values mp=reshape(mphase,m(k),[]); % find average in each "tau group" (each column of mp) pa(p,:)=mean(mp,1); % shift data vector by -1 and repeat mphase=circshift(dphase,(size(dphase)>1)*-p); end % create "modified" y_k freq values mfreq=diff(pa,1,2)./i; mfreq=reshape(mfreq,1,[]); % calculate modified frequency differences mfreqd=reshape(mfreq,m(k),[]); % Vectorize! mfreqd=diff(mfreqd,1,2); mfreqd=reshape(mfreqd,1,[]); % calculate two-sample variance for this tau sm(k)=sqrt((1/(2*(N-3*m(k)+1)))*(sum(mfreqd(1:N-3*m(k)+1).^2))); % estimate error bars sme(k)=sm(k)/sqrt(N-3*m(k)+1); end % repeat for each value of tau if verbose >= 2, fprintf(1,' '); end calctime=toc; if verbose >= 2, fprintf(1,'allan_modified: Elapsed time for calculation: %g seconds ',calctime); end |
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%% Irregular data (timestamp) elseif isfield(data,'time') |
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% the interval between measurements is irregular % so we must group the data by time if verbose >= 1, fprintf(1, 'allan_modified: irregular rate data (no fixed sample rate) '); end % string for plot title name=[name ' (timestamp)']; % adjust time to remove any initial offset dtime=data.time-data.time(1)+mean(diff(data.time)); %dtime=data.time-data.time(1); % where is the maximum gap in time record? gap_pos=find(diff(dtime)==max(diff(dtime))); % what is average data spacing? avg_gap = mean(diff(dtime)); if verbose >= 2 fprintf(1, 'allan_modified: WARNING: irregular timestamp data (no fixed sample rate). '); fprintf(1, ' Calculation time may be long and the results subject to interpretation. '); fprintf(1, ' You are advised to estimate using an average sample rate (%g Hz) instead of timestamps. ',1/avg_gap); fprintf(1, ' Continue at your own risk! (press any key to continue) '); pause; end if verbose >= 1 fprintf(1, 'allan_modified: End of timestamp data: %g sec ',dtime(end)); fprintf(1, ' Average sample rate: %g Hz (%g sec/measurement) ',1/avg_gap,avg_gap); if max(diff(dtime)) ~= 1/mean(diff(dtime)) fprintf(1, ' Max. gap in time record: %g sec at position %d ',max(diff(dtime)),gap_pos(1)); end if max(diff(dtime)) > 5*avg_gap fprintf(1, ' WARNING: Max. gap in time record is suspiciously large (>5x the average interval). '); end end % is phase data present? If not, generate it if ~isfield(data,'phase') nfreq=data.freq-s.mean; % NOTE: uncommenting the following two lines will artificially % allow the code to give equivalent results for validation data % sets using fixed rate data and timestamped data by adding a % "phantom" data point for frequency integration. Use of this % phantom point can skew the results of calculations on real data. %nfreq(end+1)=0; % phantom freq point, with average value %dtime(end+1)=dtime(end)+avg_gap; % phantom average time step dphase=zeros(1,length(nfreq)); dphase(2:end) = cumsum(nfreq(1:end-1)).*diff(dtime); if verbose >= 1, fprintf(1,'allan_modified: Phase data generated from fractional frequency data (N=%g). ',length(dphase)); end else dphase=data.phase; end % find halfway point halftime = fix(dtime(end)/2); % truncate tau to appropriate values tau = tau(tau >= max(diff(dtime)) & tau <= halftime); if isempty(tau) error('allan_modified: ERROR: no appropriate tau values (> %g s, < %g s) ',max(diff(dtime)),halftime); end % % save the freq data for the loop % dfreq=data.freq; % number of samples N=length(dphase); m=round(tau./mean(diff(dtime))); if verbose >= 1, fprintf(1,'allan_modified: calculating modified Allan deviation... '); end k=0; tic; for i = tau k=k+1; pa=[]; mphase = dphase; time = dtime; if verbose >= 2, fprintf(1,'%d ',i); end % calculate overlapping "phase averages" (x_k) %for j = 1:i for j = 1:m(k) % (v1.1) km=0; %fprintf(1,'j: %d ',j); % (v1.1) truncating not correct for overlapping samples % truncate data set to an even multiple of this tau value %mphase = mphase(time <= time(end)-rem(time(end),i)); %time = time(time <= time(end)-rem(time(end),i)); % break up the data into overlapping groups of tau length while i*km < time(end) km=km+1; % progress bar if verbose >= 2 if rem(km,100)==0, fprintf(1,'.'); end if rem(km,1000)==0, fprintf(1,'%g/%g ',km,round(time(end)/i)); end end mp = mphase(i*(km-1) < (time) & (time) <= i*km); if ~isempty(mp) pa(j,km)=mean(mp); else pa(j,km)=0; end end % shift data vector by -1 and repeat mphase=circshift(dphase,(size(mphase)>1)*-j); mphase(end-j+1:end)=[]; time=circshift(dtime,(size(time)>1)*-j); time(end-j+1:end)=[]; time=time-time(1)+avg_gap; % remove time offset end % create "modified" y_k freq values mfreq=diff(pa,1,2)./i; mfreq=reshape(mfreq,1,[]); % calculate modified frequency differences mfreqd=reshape(mfreq,m(k),[]); % Vectorize! mfreqd=diff(mfreqd,1,2); mfreqd=reshape(mfreqd,1,[]); % calculate two-sample variance for this tau % only the first N-3*m(k)+1 samples are valid if length(mfreqd) >= N-3*m(k)+1 sm(k)=sqrt((1/(2*(N-3*m(k)+1)))*(sum(mfreqd(1:N-3*m(k)+1).^2))); % estimate error bars sme(k)=sm(k)/sqrt(N); if verbose >= 2, fprintf(1,' '); end else if verbose >=2, fprintf(1,' tau=%g dropped due to timestamp irregularities ',tau(k)); end sm(k)=0; sme(k)=0; end end if verbose >= 2, fprintf(1,' '); end calctime=toc; if verbose >= 2, fprintf(1,'allan_modified: Elapsed time for calculation: %g seconds ',calctime); end % remove any points that were dropped tau(sm==0)=[]; sm(sm==0)=[]; sme(sme==0)=[]; % modify time vector for plotting dtime=dtime(1:length(medianfreq)); |
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error('allan_modified: WARNING: no DATA.rate or DATA.time! Type "help allan_modified" for more information. [err2]'); |
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end %%%%%%%% %% Plotting if verbose >= 2 % show all data |
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% plot the frequency data, centered on median if size(dtime,2) > size(dtime,1), dtime=dtime'; end % this should not be necessary, but dsplot 1.1 is a little bit brittle try % dsplot makes a new figure hd=dsplot(dtime,medianfreq); catch ME figure; hd=plot(dtime,medianfreq); if verbose >= 1, fprintf(1,'allan_modified: Note: Install dsplot.m for improved plotting of large data sets (File Exchange File ID: #15850). '); end if verbose >= 2, fprintf(1,' (Message: %s) ',ME.message); end end set(hd,'Marker','.','LineStyle','none','Color','b'); % equivalent to '.-' hold on; fx = xlim; % plot([fx(1) fx(2)],[s.median s.median],'-k'); plot([fx(1) fx(2)],[0 0],':k'); % show 5x Median Absolute deviation (MAD) values hm=plot([fx(1) fx(2)],[5*MAD 5*MAD],'-r'); plot([fx(1) fx(2)],[-5*MAD -5*MAD],'-r'); % show linear fit line hf=plot(xlim,polyval(s.linear,xlim)-s.median,'-g'); title(['Data: ' name],'FontSize',FontSize+2,'FontName',FontName); %set(get(gca,'Title'),'Interpreter','none'); xlabel('Time [sec]','FontSize',FontSize,'FontName',FontName); if isfield(data,'units') ylabel(['data - median(data) [' data.units ']'],'FontSize',FontSize,'FontName',FontName); else ylabel('freq - median(freq)','FontSize',FontSize,'FontName',FontName); end set(gca,'FontSize',FontSize,'FontName',FontName); legend([hd hm hf],{'data (centered on median)','5x MAD outliers',['Linear Fit (' num2str(s.linear(1),'%g') ')']},'FontSize',max(10,FontSize-2)); % tighten up xlim([dtime(1) dtime(end)]); |
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end % end plot raw data if verbose >= 1 % show analysis results |
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% plot Allan deviation results if ~isempty(sm) figure % Choose loglog or semilogx plot here #PLOTLOG %semilogx(tau,sm,'.-b','LineWidth',plotlinewidth,'MarkerSize',24); loglog(tau,sm,'.-b','LineWidth',plotlinewidth,'MarkerSize',24); % in R14SP3, there is a bug that screws up the error bars on a semilog plot. % When this is fixed, uncomment below to use normal errorbars %errorbar(tau,sm,sme,'.-b'); set(gca,'XScale','log'); % this is a hack to approximate the error bars hold on; plot([tau; tau],[sm+sme; sm-sme],'-k','LineWidth',max(plotlinewidth-1,2)); grid on; title(['Modified Allan Deviation: ' name],'FontSize',FontSize+2,'FontName',FontName); %set(get(gca,'Title'),'Interpreter','none'); xlabel('\tau [sec]','FontSize',FontSize,'FontName',FontName); ylabel('Modified \sigma_y(\tau)','FontSize',FontSize,'FontName',FontName); set(gca,'FontSize',FontSize,'FontName',FontName); % expand the x axis a little bit so that the errors bars look nice adax = axis; axis([adax(1)*0.9 adax(2)*1.1 adax(3) adax(4)]); % display the minimum value fprintf(1,'allan: Minimum modified ADEV value: %g at tau = %g seconds ',min(sm),tau(sm==min(sm))); elseif verbose >= 1 fprintf(1,'allan_modified: WARNING: no values calculated. '); fprintf(1,' Check that TAU > 1/DATA.rate and TAU values are divisible by 1/DATA.rate '); fprintf(1,'Type "help allan_modified" for more information. '); end |
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end % end plot analysis |
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retval = sm; errorb = sme; return |