@article{ author = {}, title = {asww}, abstract ={Abstract of spoken word recognition is proposed. This model is particularly concerned with extraction of cues from the signal leading to a specification of a word in terms of bundles of distinctive features, which are assumed to be the building blocks of words. In the model proposed, auditory input is chunked into a set of successive time slices. It is assumed that the derivation of the underlying word pattern proceeds in three layers: Features, phonemes, words. The feature layer has a complete set of feature detectors at every time slice. In this layer, the detection of the underlying pattern of distinctive features from the speech signal proceeds in three steps. In the first step, numerical values for features are obtained measuring acoustic attributes in each time slice. The acoustic attributes are either acoustic landmarks corresponding to articulator-free features which are identified, based on amplitude changes in various energy bands, or acoustic cues in the vicinity of the landmarks corresponding to articulator-bound features. Continuous perceptual feature values are, then processed into a much more structured representation, namely phonological surface structure. This is carried out in Perception Grammar as suggested by Boersma (1998). In the third step, a further processing is carried out to turn the discrete representation into an abstract one yielding the underlying pattern of distinctive features. The next layer of the model has a complete set of phoneme detectors for every three time slices, but each set spans six time slices so the sets overlap. This means that the detection of adjacent phonemes will also overlap; this is supposed to simulate coarticulation. The top layer has a complete set of word detectors centered on every three time slices; again, the sets overlap, the number of time slices per word detector is variable because it depends on the length of each individual word.}, Keywords = {Optimality- Perception Grammar- Recognition Grammar- Acoustic constrai}, volume = {5}, Number = {2}, pages = {3-16}, publisher = {Research Center on Developing Advanced Technologies}, url = {http://jsdp.rcisp.ac.ir/article-1-747-en.html}, eprint = {http://jsdp.rcisp.ac.ir/article-1-747-en.pdf}, journal = {Signal and Data Processing}, issn = {2538-4201}, eissn = {2538-421X}, year = {2009} } @article{ author = {}, title = {Classification of Memory Correlated Event Related Potentials in Old/New Items Recall using Time-Frequency Features}, abstract ={Abstract: The object of this research is development of memory assessment system, using Event Related Potentials. Our approach is using ERPs recorded on Fz, Cz and Pz electrodes. Subjects made old/new recognition judgments on new unstudied unmeaning pictures and old pictures which had been presented at study phase. Features related with memory activity in time-frequency domain were used to achieve this purpose. So that discrete wavelet transform coefficients of Event Related Potentials computed, then using mean, variance and power of specific frequency bands, 36 features on 3 channels were obtained entirely. After appropriate feature selection on single and three channels Linear discriminant analysis was done to get classification results using selected features. Finally we discriminated groups with 89.3% accuracy in test group by combination of three channels features.}, Keywords = {Memory, Event Related Potentials, discrete wavelet transform, Linear Discriminant Analysis, Feature selection.}, volume = {5}, Number = {2}, pages = {17-28}, publisher = {Research Center on Developing Advanced Technologies}, url = {http://jsdp.rcisp.ac.ir/article-1-748-en.html}, eprint = {http://jsdp.rcisp.ac.ir/article-1-748-en.pdf}, journal = {Signal and Data Processing}, issn = {2538-4201}, eissn = {2538-421X}, year = {2009} } @article{ author = {}, title = {asas}, abstract ={asdgaa}, Keywords = {asdadad}, volume = {5}, Number = {2}, pages = {29-40}, publisher = {Research Center on Developing Advanced Technologies}, url = {http://jsdp.rcisp.ac.ir/article-1-749-en.html}, eprint = {http://jsdp.rcisp.ac.ir/article-1-749-en.pdf}, journal = {Signal and Data Processing}, issn = {2538-4201}, eissn = {2538-421X}, year = {2009} } @article{ author = {}, title = {asda}, abstract ={asdad}, Keywords = {asda}, volume = {5}, Number = {2}, pages = {41-56}, publisher = {Research Center on Developing Advanced Technologies}, url = {http://jsdp.rcisp.ac.ir/article-1-750-en.html}, eprint = {http://jsdp.rcisp.ac.ir/article-1-750-en.pdf}, journal = {Signal and Data Processing}, issn = {2538-4201}, eissn = {2538-421X}, year = {2009} } @article{ author = {}, title = {Quadratic B-Spline Wavelet and Committee Machine for the P300 Detection in Brain Computer Interface}, abstract ={Abstract: In this study we propose a new approach to analyze data from the P300 speller paradigm using the quadratic B-Spline wavelet coefficients in comparing to time and frequency features sets on the event related potentials. Data set II from the BCI competition 2005 was used. Mode frequency, Mean frequency, Median frequency and some morphologic parameters ware extracted as features. Three methods were used for comparing three feature subsets, first Davies Bouldin criteria, correlation based method and classification accuracy criteria. For all criteria, best result was extracted from wavelet coefficients, at the final wavelet coefficients were used as inputs into committee machines (CM) based on LDA, MLP and SVM. This algorithm achieved an accuracy of 97.6% for train data and 94.2% for test data of subject A in target and non target detection also accuracy of 98.2% for train data and 92.8% for test data of subject B.}, Keywords = { P300 Component, Wavelet Transform, BCI Speller 2005 and Committee Machines}, volume = {5}, Number = {2}, pages = {57-70}, publisher = {Research Center on Developing Advanced Technologies}, url = {http://jsdp.rcisp.ac.ir/article-1-751-en.html}, eprint = {http://jsdp.rcisp.ac.ir/article-1-751-en.pdf}, journal = {Signal and Data Processing}, issn = {2538-4201}, eissn = {2538-421X}, year = {2009} } @article{ author = {}, title = {Detection of cerebral micro emboli in Doppler Signal using nonlinear features}, abstract ={Abstract: An embolus is a blood clot, a fat globule or gas bubbles that may be freely circulating in bloodstream can stop the blood flow and lead to ischemia. In real time assessment of blood flow by Trans Cranial Doppler (TCD) method, travelling solid or gaseous micro emboli in the bloodstream by passing across the assessment area, causes a short time signal with high intensity. While TCD recording including movement of the probe, coughing, sneezing, and head rotation generate high intensity artifacts that make it difficult to make differentiate from embolus. Time consuming and also human mistakes in differentiating emboli from artifact are the main motivations of design of the automatic detection systems. Implementing such systems is nowadays faced with two main challengeous problems: extracting suitable features and designing the proper classifier. In this research, we studied two issues together. In feature extraction part, wavelet coeffiecient, wavelet entropy, fractal dimention and Besov property of signal is extracted, and using by statistical methods we introduced the feature with highest separability rate. In classifier part, a novel method based on hidden markov models for detecting emboli from artifact is proposed, and the results is compared with the results of Adaptive Neuro Fuzzy Inference System classifier. In total, using wavelet coefficients and hidden markov model, we achieved an accuracy rate of 95.3% and specificity of 92.7%.}, Keywords = {MES, Adaptive Neuro Fuzzy Inference System (ANFIS), Hidden Markov Model (HMM), Entropy, Wavelet coefficients.}, volume = {5}, Number = {2}, pages = {71-85}, publisher = {Research Center on Developing Advanced Technologies}, url = {http://jsdp.rcisp.ac.ir/article-1-752-en.html}, eprint = {http://jsdp.rcisp.ac.ir/article-1-752-en.pdf}, journal = {Signal and Data Processing}, issn = {2538-4201}, eissn = {2538-421X}, year = {2009} } @article{ author = {}, title = {Asdad}, abstract ={asdafdf}, Keywords = {asdad}, volume = {5}, Number = {2}, pages = {85-104}, publisher = {Research Center on Developing Advanced Technologies}, url = {http://jsdp.rcisp.ac.ir/article-1-753-en.html}, eprint = {http://jsdp.rcisp.ac.ir/article-1-753-en.pdf}, journal = {Signal and Data Processing}, issn = {2538-4201}, eissn = {2538-421X}, year = {2009} }