System and method for electric load identification and classification employing support vector machine

What is claimed is: 1. A method of identifying electric load types of a plurality of different electric loads, said method comprising: providing a support vector machine load feature database of a plurality of different electric load types; sensing a voltage signal and a current signal for each of said different electric loads; determining a load feature vector including at least six steady-state features with a processor from said sensed voltage signal and said sensed current signal; and identifying one of said different electric load types by relating the load feature vector including the at least six steady-state features to the support vector machine load feature database. 2. The method of claim 1 further comprising: training said support vector machine load feature database as a multi-class one-against-all support vector machine for each of a plurality of different load classes or for each of said different electric load types. 3. The method of claim 2 further comprising: employing as said different load classes seven different load classes having distinct steady-state features, said seven different load classes including resistive loads, reactive predominant loads, electronic loads with a power factor correction circuit, electronic loads without a power factor correction circuit, linear power supplies using a transformer to boost voltage, phase angle controllable loads, and complex structures. 4. The method of claim 2 further comprising: employing said different electric load types having distinct steady-state features. 5. The method of claim 1 further comprising: employing a Gaussian radial basis functions kernel with said support vector machine load feature database. 6. The method of claim 1 further comprising: representing voltage and current waveforms corresponding to said sensed voltage signal and said sensed current signal, respectively, by Fourier series. 7. The method of claim 1 further comprising: employing said at least six steady-state features selected from the group consisting of RMS current value, displacement power factor, total harmonic distortion of current, power factor, current crest factor, current K-factor, admittance, and normalized current third and fifth harmonics. 8. A method of identifying electric load types of a plurality of different electric loads, said method comprising: providing a database including a first layer formed by a supervised self-organizing map database and a second layer formed by a support vector machine database; clustering a plurality of different load classes having a plurality of different load features in the first layer; providing a plurality of different electric load types under each of the different load classes in the second layer; placing different ones of said different electric load types having similar load feature vectors into a same one of the different load classes; sensing a voltage signal and a current signal for each of said different electric loads; determining a load feature vector including a plurality of steady-state features with a processor from said sensed voltage signal and said sensed current signal; and identifying by a support vector machine one of said different electric load types by relating the determined load feature vector including the steady-state features in the second layer of said database. 9. The method of claim 8 further comprising: employing as said different load classes seven different load classes having distinct steady-state features, said seven different load classes including resistive loads, reactive predominant loads, electronic loads with a power factor correction circuit, electronic loads without a power factor correction circuit, linear power supplies using a transformer to boost voltage, phase angle controllable loads, and complex structures. 10. The method of claim 8 further comprising: training the supervised self-organizing map database employing data corresponding to the different electric load types; training the support vector machine database as a multi-class one-against-all support vector machine for each of said plurality of different load classes; identifying said one of said different electric load types as being in one of said plurality of different load classes with said supervised self-organizing map database; and identifying said one of said different electric load types with the trained support vector machine database for said one of said plurality of different load classes. 11. The method of claim 10 further comprising: extracting information from the trained support vector machine database and storing simplified information in a trained neuron grid; employing as said different load classes a plurality of different load categories; determining one of the different load categories employing the determined load feature vector; and employing a support vector machine discriminator function for each the different load categories to identify said one of said different electric load types. 12. The method of claim 10 further comprising: employing as said different load classes seven different load classes having distinct steady-state features, said seven different load classes including resistive loads, reactive predominant loads, electronic loads with a power factor correction circuit, electronic loads without a power factor correction circuit, linear power supplies using a transformer to boost voltage, phase angle controllable loads, and complex structures. 13. The method of claim 8 further comprising: representing voltage and current waveforms corresponding to said sensed voltage signal and said sensed current signal, respectively, by Fourier series. 14. The method of claim 8 further comprising: selecting the steady-state features of said determined load feature vector from the group consisting of RMS current value, displacement power factor, total harmonic distortion of current, power factor, current crest factor, current K-factor, admittance, and normalized current third and fifth harmonics. 15. The method of claim 8 further comprising: including with the steady-state features of said determined load feature vector voltage-current trajectory features selected from the group consisting of area, eccentricity, and Hausdorff distance. 16. A system for identifying electric load types of a plurality of different electric loads, said system comprising: a database including a first layer formed by a supervised self-organizing map database and a second layer formed by a support vector machine database, a plurality of different load classes having a plurality of different load features being clustered in the first layer, a plurality of different electric load types being under each of the different load classes in the second layer, different ones of said different electric load types having similar load feature vectors being placed into a same one of the different load classes; a plurality of sensors structured to sense a voltage signal and a current signal for each of said different electric loads; and a processor structured to determine a load feature vector including a plurality of steady-state features from said sensed voltage signal and said sensed current signal, and identify by a support vector machine one of said different electric load types by relating the determined load feature vector including the steady-state features in the second layer of said database. 17. The system of claim 16 wherein said processor is further structured to train the supervised self-organizing map database employing