Name
classify_class_gmmT_classify_class_gmmClassifyClassGmmclassify_class_gmmClassifyClassGmmClassifyClassGmm — Calculate the class of a feature vector by a Gaussian Mixture
Model.
Herror classify_class_gmm(const HTuple& GMMHandle, const HTuple& Features, const HTuple& Num, HTuple* ClassID, HTuple* ClassProb, HTuple* Density, HTuple* KSigmaProb)
HTuple HClassGmm::ClassifyClassGmm(const HTuple& Features, const HTuple& Num, HTuple* ClassProb, HTuple* Density, HTuple* KSigmaProb) const
void ClassifyClassGmm(const HTuple& GMMHandle, const HTuple& Features, const HTuple& Num, HTuple* ClassID, HTuple* ClassProb, HTuple* Density, HTuple* KSigmaProb)
HTuple HClassGmm::ClassifyClassGmm(const HTuple& Features, Hlong Num, HTuple* ClassProb, HTuple* Density, HTuple* KSigmaProb) const
void HOperatorSetX.ClassifyClassGmm(
[in] VARIANT GMMHandle, [in] VARIANT Features, [in] VARIANT Num, [out] VARIANT* ClassID, [out] VARIANT* ClassProb, [out] VARIANT* Density, [out] VARIANT* KSigmaProb)
VARIANT HClassGmmX.ClassifyClassGmm(
[in] VARIANT Features, [in] Hlong Num, [out] VARIANT* ClassProb, [out] VARIANT* Density, [out] VARIANT* KSigmaProb)
static void HOperatorSet.ClassifyClassGmm(HTuple GMMHandle, HTuple features, HTuple num, out HTuple classID, out HTuple classProb, out HTuple density, out HTuple KSigmaProb)
HTuple HClassGmm.ClassifyClassGmm(HTuple features, int num, out HTuple classProb, out HTuple density, out HTuple KSigmaProb)
classify_class_gmmclassify_class_gmmClassifyClassGmmclassify_class_gmmClassifyClassGmmClassifyClassGmm computes the best NumNumNumNumNumnum classes of
the feature vector FeaturesFeaturesFeaturesFeaturesFeaturesfeatures with the Gaussian Mixture Model
(GMM) GMMHandleGMMHandleGMMHandleGMMHandleGMMHandleGMMHandle and returns the classes in ClassIDClassIDClassIDClassIDClassIDclassID
and the corresponding probabilities of the classes in
ClassProbClassProbClassProbClassProbClassProbclassProb. Before calling classify_class_gmmclassify_class_gmmClassifyClassGmmclassify_class_gmmClassifyClassGmmClassifyClassGmm, the
GMM must be trained with train_class_gmmtrain_class_gmmTrainClassGmmtrain_class_gmmTrainClassGmmTrainClassGmm.
classify_class_gmmclassify_class_gmmClassifyClassGmmclassify_class_gmmClassifyClassGmmClassifyClassGmm corresponds to a call to
evaluate_class_gmmevaluate_class_gmmEvaluateClassGmmevaluate_class_gmmEvaluateClassGmmEvaluateClassGmm and an additional step that extracts the
best NumNumNumNumNumnum classes. As described with
evaluate_class_gmmevaluate_class_gmmEvaluateClassGmmevaluate_class_gmmEvaluateClassGmmEvaluateClassGmm, the output values of the GMM can be
interpreted as probabilities of the occurrence of the respective
classes. However, here the posterior probability ClassProbClassProbClassProbClassProbClassProbclassProb
is further normalized as ClassProbClassProbClassProbClassProbClassProbclassProb = p(i|x)/p(x)
, where p(i|x) and p(x) are specified with evaluate_class_gmmevaluate_class_gmmEvaluateClassGmmevaluate_class_gmmEvaluateClassGmmEvaluateClassGmm.
In most cases it should be sufficient to use NumNumNumNumNumnum =
1 in order to decide whether the
probability of the best class is high enough. In some applications
it may be interesting to also take the second best class into
account (NumNumNumNumNumnum = 2), particularly if it can be
expected that the classes show a significant degree of overlap.
DensityDensityDensityDensityDensitydensity and KSigmaProbKSigmaProbKSigmaProbKSigmaProbKSigmaProbKSigmaProb are explained with
evaluate_class_gmmevaluate_class_gmmEvaluateClassGmmevaluate_class_gmmEvaluateClassGmmEvaluateClassGmm.
- Multithreading type: reentrant (runs in parallel with non-exclusive operators).
- Multithreading scope: global (may be called from any thread).
- Processed without parallelization.
Number of best classes to determine.
Default value: 1
Suggested values: 1, 2, 3, 4, 5
Result of classifying the feature vector with
the GMM.
A-posteriori probability of the classes.
Probability density of the feature vector.
Normalized k-sigma-probability for the feature
vector.
If the parameters are valid, the operator classify_class_gmmclassify_class_gmmClassifyClassGmmclassify_class_gmmClassifyClassGmmClassifyClassGmm
returns the value 2 (H_MSG_TRUE). If necessary an exception is
raised.
train_class_gmmtrain_class_gmmTrainClassGmmtrain_class_gmmTrainClassGmmTrainClassGmm,
read_class_gmmread_class_gmmReadClassGmmread_class_gmmReadClassGmmReadClassGmm
evaluate_class_gmmevaluate_class_gmmEvaluateClassGmmevaluate_class_gmmEvaluateClassGmmEvaluateClassGmm
create_class_gmmcreate_class_gmmCreateClassGmmcreate_class_gmmCreateClassGmmCreateClassGmm
Christopher M. Bishop: “Neural Networks for Pattern Recognition”;
Oxford University Press, Oxford; 1995.
Mario A.T. Figueiredo: “Unsupervised Learning of Finite Mixture
Models”; IEEE Transactions on Pattern Analysis and Machine
Intelligence, Vol. 24, No. 3; March 2002.
Foundation