CHARACTERIZATION OF THE EFFICIENCY OF THE FEATURES AGGREGATE IN FUZZY PATTERN RECOGNITION TASK

Environment Technology Resources Proceedings of the International Scientific and Practical Conference ◽

10.17770/etr1997vol1.1858 ◽

1997 ◽

Vol 1 ◽

pp. 78

Author(s):

R. Grekov ◽

A. Borisov

Keyword(s):

Pattern Recognition ◽

Decision Rule ◽

Recognition Task ◽

Dimensional Vector ◽

Fuzzy Pattern Recognition ◽

Fuzzy Pattern ◽

The Given ◽

Pattern Recognition Task

Let a set of objects exist each of which is described by N features X1? ..., XN, where each feature X} is a real number. So each object is set by N-dimensional vector (Xl5 ..., XN) and represents a point in the space of object descriptions, RN.There are also set objects for which degrees of membership in either class are unknown. A decision rule should be determined that could enable estimation of the membership of either object with unknown degrees of membership in the given classes (Ozols and Borisov, 1996). To determine the decision rule, such features should be found which give a possibility to distinguish objects belonging to different classes, i.e. features that are specific for each class. That is why a subtask of estimation of the efficiency of features should be solved. A function 5 should be determined which could enable estimation of the efficiency of both separate features and of features groups.Thus, the task is reduced to the determination of a number of features from set N that will best describe groups of objects and will enable possibly correct recognition of the object's membership in a class.

Download Full-text

Determination of doneness of beef steaks using fuzzy pattern recognition

Journal of Food Engineering ◽

10.1016/0260-8774(88)90056-8 ◽

1988 ◽

Vol 8 (2) ◽

pp. 79-90 ◽

Cited By ~ 4

Author(s):

Kenneth Unklesbay ◽

James Keller ◽

Nan Unklesbay ◽

Deeka Subhangkasen

Keyword(s):

Pattern Recognition ◽

Fuzzy Pattern Recognition ◽

Fuzzy Pattern ◽

Beef Steaks

Download Full-text

Laser tailored blanks weld quality monitoring algorithm by using fuzzy pattern recognition

International Congress on Applications of Lasers & Electro-Optics ◽

10.2351/1.5059539 ◽

2000 ◽

Author(s):

S. Rhee ◽

H. Park ◽

Y. Park

Keyword(s):

Pattern Recognition ◽

Quality Monitoring ◽

Weld Quality ◽

Fuzzy Pattern Recognition ◽

Tailored Blanks ◽

Fuzzy Pattern ◽

Monitoring Algorithm

Download Full-text

The Heartbeat Classification Based on PCA

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.195-196.402 ◽

2012 ◽

Vol 195-196 ◽

pp. 402-406

Author(s):

Xue Qin Chen ◽

Rui Ping Wang

Keyword(s):

Principal Component Analysis ◽

Pattern Recognition ◽

Recognition Task ◽

Principal Component ◽

True Positive Rate ◽

True Positive ◽

Heartbeat Classification ◽

Positive Rate ◽

Electrocardiogram Ecg ◽

Pattern Recognition Task

Classify the electrocardiogram (ECG) into different pathophysiological categories is a complex pattern recognition task which has been tried in lots of methods. This paper will discuss a method of principal component analysis (PCA) in exacting the heartbeat features, and a new method of classification that is to calculate the error between the testing heartbeat and reconstructed heartbeat. Training and testing heartbeat is taken from the MIT-BIH Arrhythmia Database, in which 8 types of arrhythmia signals are selected in this paper. The true positive rate (TPR) is 83%.

Download Full-text

Electric Source Localization Adds Evidence for Task-Specific CNVs

Behavioural Neurology ◽

10.1155/1998/728634 ◽

1998 ◽

Vol 11 (1) ◽

pp. 21-28 ◽

Cited By ~ 4

Author(s):

Ina M. Tarkka ◽

Luis F. H. Basile

Keyword(s):

Pattern Recognition ◽

Source Localization ◽

Clinical Neurophysiology ◽

Recognition Task ◽

Source Analysis ◽

Visual Spatial ◽

Spatio Temporal ◽

Electric Source ◽

Pattern Recognition Task ◽

Spatial Recognition

This study was an attempt to replicate recent magnetoencephalographic (MEG) findings on human task-specific CNV sources (Basile et al., Electroencephalography and Clinical Neurophysiology 90, 1994, 157–165) by means of a spatio-temporal electric source localization method (Scherg and von Cramon, Electroencephalography and Clinical Neurophysiology 62, 1985, 32–44; Scherg and von Cramon, Electroencephalography and Clinical Neurophysiology 65, 1986, 344-360; Scherg and Berg, Brain Electric Source Analysis Handbook, Version 2). The previous MEG results showed CNV sources in the prefrontal cortex of the two hemispheres for two tasks used, namely visual pattern recognition and visual spatial recognition tasks. In the right hemisphere, the sources were more anterior and inferior for the spatial recognition task than for the pattern recognition task. In the present study we obtained CNVs in five subjects during two tasks identical to the MEG study. The elicited electric potentials were modeled with four spatio-temporal dipoles for each task, three of which accounted for the visual evoked response and one that accounted for the CNV. For all subjects the dipole explaining the CNV was always localized in the frontal region of the head, however, the dipole obtained during the visual spatial recognition task was more anterior than the one obtained during the pattern recognition task. Thus, task-specific CNV sources were again observed, although the stable model consisted of only one dipole located close to the midline instead of one dipole in each hemisphere. This was a major difference in the CNV sources between the previous MEG and the present electric source analysis results. We discuss the possible basis for the difference between the two methods used to study slow brain activity that is believed to originate from extended cortical patches.

Download Full-text