-
Notifications
You must be signed in to change notification settings - Fork 28
Objective function, likelhood and chi square in the d2d framework
At this page, the following aspects and their relationships are explained:
- How is objective function used for parameter estimation calculated?
- What's done in arChi2?
- What's plotted on the vertical axis of the profile likelihood plots?
- How are priors considered?
- What's the impact of the number of parameters?
- What's the impact of fitting error parameters?
- Why is
ar.chi2
unequal tosum(ar.res.^2)
? - What's the Bessel correction?
- Is it possible to assess whether the model is in agreement with the data?
- Evaluation of the objective function used in optimization:
#!matlab
sum([ar.res,ar.constr].^2)
- Goodnes-of-Fit, i.e. -2*log(L):
#!matlab
2*ar.ndata*log(sqrt(2*pi)) + ar.chi2fit
or output of
#!matlab
2*ar.ndata*log(sqrt(2*pi)) + ar.chi2fit
or if ple has been performed
#!matlab
feval(pleGlobals.merit_fkt)
- Standard chi-square:
#!matlab
ar.config.fiterrors = 0;
arChi2
ar.chi2
The objective function, also called merit function, is defined in arFit.m. The optimizer calls the merit-function which, in turn, calls arChi2 to update the model and the residuals.
By default, @lsqnonlin is used for optimization. Lsqnonlin works with residuals res which are internally squared and summed up, i.e. lsqnonlin minimizes sum(res.^2)
where
#!matlab
res = [ar.res ar.constr] .
In d2d, the residual vector of the whole model (ar.res
) consists of
- the union of all residuals of the individual data sets ar.model.data.res
- and the residuals originating from penalties of for the individual parameters.
- When error model parameters are fitted, the union of ar.model.data.reserr is also added.
If steady-state constraints are used, ar.constr is added to ar.res
for optimization.
The comprehensive objective function can be calculated by hand via
#!matlab
sum([ar.res,ar.constr].^2).
arChi2
is the major function for assessing the mismatch between model and data.
arChi2
calls arSimu
and therefore integrates the ODE and updates the model predictions based on the current parameters in ar.p
.
The following variables are calculated for assessing the goodness-of-fit:
-
ar.ndata
, i.e. the number of data points used for fitting -
ar.config.fiterrors_correction
which is the Bessel correction given by
#!matlab
ar.config.fiterrors_correction = ar.ndata/(ar.ndata-sum(ar.qError~=1 & ar.qFit==1));
-
ar.chi2
contains the contribution of data and prior. It is the sum ofar.model(m).data(d).chi2
for all models m and all data sets d which are used for fitting (ar.model.data.qFit) plus potential terms originating from parameter priors. -
ar.chi2err
is the sum of allar.model(m).data(d).chi2err
from all parameter dependent measurement errors, if used for fitting according toar.model.data.qFit
. -
ar.chi2prior
is the sum of penalties originating from priors for parameters. For Gaussian priors, the penalties have to following form:
(ar.mean(jp)-ar.p(jp))./ar.std(jp).
-
ar.chi2constr
is a penalty which is used when steady state constraints are introduced for dx/dt at the first time point. Qualitatively, such constraints are penalized by
(dxdt ./ x) ./ ar.model(m).condition(c).stdSteadyState.
-
ar.chi2fit
coincides with ar.chi2 if the error parameters are not fitted. Otherwise it is
ar.chi2fit = ar.chi2+ar.chi2err.
The output written by arChi2.m at the command line is
-2 log(L) = 2*ar.ndata*log(sqrt(2*pi)) + ar.chi2fit
and looks the following:
#!matlab
>> arChi2
-2*log(L) = -130.824, 46 data points, 16 free parameters, first order optimality criterion 0.340897 (0)
Negative values for -2*log(L) only occur if error parameters are fitted, i.e. if ar.config.fiterrors==1
. The standard chi-square is obtained by
#!matlab
>> ar.config.fiterrors=0;
>> arChi2
global chi^2 = 33.0002, 46 data points, 16 free parameters, first order optimality criterion 0.244546 (0)
Note that the estimated parameters in general depend on the fitted errors. Therefore, when ar.config.fiterrors is altered, the minimum changes.
In the case of fitted error parameters, there is a mismatch between the objective function used for optimization which is based on ar.res and ar.model.data.reserr and all the chi2* fields in the global ar struct which are based on ar.model.data.chi2err
.
The magnitude of ar.model.data.reserr
should be proportional to the square root of the contribution of the standard deviation parameters in the log-likelihood. To omit negative arguments in the square root, i.e. negative values for 2*log(ystd)
, an additive constant add_c=50 is added in arSimuCalc.c.
#!c
double add_c = 50.0;
(...)
reserr[it + (iy*nt)] = 2.0*log(ystd[it + (iy*nt)]);
(...)
reserr[it + (iy*nt)] += add_c;
if(reserr[it + (iy*nt)] < 0) {
printf("ERROR error model < 1e-10 not allowed\n");
return;
}
reserr[it + (iy*nt)] = sqrt(reserr[it + (iy*nt)]);
chi2err[iy] += pow(reserr[it + (iy*nt)], 2) - add_c;
The constant add_c
does not change the optimum, but the order of magnitude of the residuals and merit-function. The additive constant does not enter ar.model.data.chi2err. This is the reason why the output fval of the optimizer as well as ar.chi2fit and all other fields ar.chi2\*
are not comparable to ar.res
when error parameters are fitted.
The vertical axis of the likelihood profiles is given by pleGlobals.chi2s
and contains the contribution of data and priors to the objective function.
It is calculated in the following manner:
pleGlobals.chi2s
is obtained by evaluating all parameter vectors obtained by
the profile likelihood calculation and coincides with pleGlobals.chi2
for a single parameter vector.
pleGlobals.chi2
is calculated by evaluating pleGlobal.merit_fkt
which in turn is defined in arPLEInit.m as arPLEMerit
. In arPLEMerit
, the following formulas are used:
#!matlabT
if(ar.config.fiterrors == 1)
chi2 = 2*ar.ndata*log(sqrt(2*pi)) + ar.chi2fit;
else
chi2 = ar.chi2;
end
arPrint indicates the type of prior in the last column. The following priors or respective penalties are available:
-
ar.type(jp)==0
: Parameters without priors. Such parameters only have lower and upper founds defined inar.lb
andar.ub
. -
ar.type(jp)==1
: Parameters with L2 penalty corresponding to a normally distributed prior. -
ar.type(jp)==3
: Parameters with L1 penalty.
If there is no prior impact in the whole model, ar.chi2prior==0
.
If L1 or L2 priors are used, then the penalty terms are calculated in arChi2
and enter ar.chi2prior
, ar.chi2
and ar.chi2fit
.
In addition ar.res
is augmented in arChi2
by additional entries for the penalties.
If priors are used, the contribution of the priors is printed at the command line
#!matlab
>> arChi2
global chi^2 = 21.9374, 47 data points, 16 free parameters, 1.254 violation of 1 prior assumptions, ...
In this context, the number of parameters corresponds to the number of fitted parameters and therefore depends on ar.qFit
.
If the Bessel correction is active, the outcome of arChi2
depends on the number of parameters
because the residuals of the data depend on the fiterrors_correction (arSimuCalc.c):
#!
res[it + (iy*nt)] = (yexp[it + (iy*nt)] - y[it + (iy*nt)]) / ystd[it + (iy*nt)] * sqrt(fiterrors_correction);
Since the fiterrors_correction enters each data residual in the same way, the fit does not depend on the number of fitted parameters. This situation can slightly change, if errors are fitted and/or priors and/or steady state constraints are used.
-
ar.config.fiterrors = 0
In this case,
- the Bessel correction is switched off in
arChi2
by settingar.config.fiterrors_correction = 1
and - the error residuals ar.model.data.reserr are ignored for fitting and for calculating ar.res.
ar.config.fiterrors = 1
- The error residuals contribute to fitting.
- If
ar.config.useFitErrorCorrection==1
, the Bessel correction is performed.
Maximum likelihood estimation yields biased estimates for error parameters in the finite sample case. The so-called Bessel correction has been suggested to modify the likelihood for reducing the bias of estimated variances.
The well-known formula
#!matlab
SD = 1/(n-1) * sum (yexp-mean).^2
is the Bessel correction of the Maximum Likelihood estimator
#!matlab
SD_MLE = 1/n * sum (yexp-mean).^2
This example illustrates the general principle: The number of data points is replaced by the degrees of freedom, i.e. the number of data points minus the number of location parameters.
In d2d
#!matlab
ar.config.fiterrors_correction = ar.ndata/(ar.ndata-sum(ar.qError~=1 & ar.qFit==1));
is used for the Bessel correction and it enters into the residuals in arSimuCalc.c by
#!matlab
res[it + (iy*nt)] = (yexp[it + (iy*nt)] - y[it + (iy*nt)]) / ystd[it + (iy*nt)] * sqrt(fiterrors_correction);
If measurement errors are known, then the chi-square goodness of fit statistic should be in the same order of magnitude as the degrees of freedom, i.e. ar.chi2fit
should be similar to ar.ndata - sum(ar.qFit==1).
The corresponding statistical test is the frequently applied goodness-of-fit test which is implemented in d2d in as arChi2Test.
Please note, that the goodness-of-fit test strongly depends on correct measurement errors. It primarily assesses whether the errors fit and is therefore not recommended to assess whether the dynamics of the model fit the data.
Estimating error model parameters as a first step and then applying the goodness-of-fit test is not valid.
A more reliable procedure for comparing several models is given by the likelihood ratio test. This method is also applicable if error parameters are fitted. Since applicability and interpretation of likelihood ratio tests is a complex topic, we refer to the scientific literature at this point.
arPlotResiduals
can be used to assess the distribution of the residuals by a QQ-plot or by their auto-correlation.
- Installation and system requirements
- Setting up models
- First steps
- Advanced events and pre-equilibration
- Computation of integration-based prediction bands
- How is the architecture of the code and the most important commands?
- What are the most important fields of the global variable ar?
- What are the most important functions?
- Optimization algorithms available in the d2d-framework
- Objective function, likelhood and chi-square in the d2d framework
- How to set up priors?
- How to set up steady state constraints?
- How do I restart the solver upon a step input?
- How to deal with integrator tolerances?
- How to implement a bolus injection?
- How to implement washing and an injection?
- How to implement a moment ODE model?
- How to run PLE calculations on a Cluster?