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Thyagharajan, K. K.
- A Novel Multiple Unsupervised Algorithm for Land Use/Land Cover Classification
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Authors
Affiliations
1 Department of Computer Science and Engineering, S. A. Engineering College, Chennai - 600077, Tamil Nadu, IN
2 R. M. D Engineering College, Kavaraipettai - 601206, IN
3 Department of Computer Science and Engineering, M. S. University, Tirunelveli - 627012,Tamil Nadu, IN
4 Department of Geography, University of Madras, Chennai - 600005, Tamil Nadu, IN
1 Department of Computer Science and Engineering, S. A. Engineering College, Chennai - 600077, Tamil Nadu, IN
2 R. M. D Engineering College, Kavaraipettai - 601206, IN
3 Department of Computer Science and Engineering, M. S. University, Tirunelveli - 627012,Tamil Nadu, IN
4 Department of Geography, University of Madras, Chennai - 600005, Tamil Nadu, IN
Source
Indian Journal of Science and Technology, Vol 9, No 42 (2016), Pagination:Abstract
Objectives: To classify the satellite images into different land use/land cover classes such as water, building, cropland, forest, etc, to monitor the environmental impacts. Method: In this paper, images are grouped into various clusters using a novel SVD trace function clustering algorithm. The clustered samples are used as a training set in a novel unsupervised Ensemble Minimization Learning algorithm (EML) for classification. The main aim of using EML is to classify the forest, vegetative land patterns, build up area in rural and urban areas with the use of best accuracy rate. Finding: Our proposed methods provides 90.56% classification rate with low error rate. This EML applies multinomial probit model and ensembles simulated data set and improves the learning of nonlinear relationships between the classified attributes. Multinomial probit model is used to bring all the related possible segmented values to fall into one single category, thus increasing the classification accuracy. Our proposed methods experimented with three different real data sets. The experimental results indicate that our proposed unsupervised model outperforms than the previous techniques. Application: It could be using for land use/land cover change detection, under water object identification, coastal area monitoring, etc. Improvement: In future it could be apply in video data and could be improve the classification accuracy also.Keywords
Ensemble Minimization Learning algorithm, Land use/Land Cover Classification, Multinominal Probit Model, SVD Trace Function, Unsupervised Algorithm.- A Review of Downlink Packet Scheduling Algorithms for Real Time Traffic in LTE-Advanced Networks
Abstract Views :154 |
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Authors
Affiliations
1 Dr. Pauls Engineering College, Puducherry - 605109, Tamil Nadu, IN
2 Jaya College of Engineering and Technology, Chennai – 600056, Tamil Nadu, IN
3 R. M. D. Engineering College, Chennai - 600040, Tamil Nadu, IN
1 Dr. Pauls Engineering College, Puducherry - 605109, Tamil Nadu, IN
2 Jaya College of Engineering and Technology, Chennai – 600056, Tamil Nadu, IN
3 R. M. D. Engineering College, Chennai - 600040, Tamil Nadu, IN
Source
Indian Journal of Science and Technology, Vol 9, No 4 (2016), Pagination:Abstract
Objective: In recent times, the demand for high data rates is ever increasing in any wireless network environment. Long Term Evolution-Advanced (LTE-A) is the latest 4G technology which is developed based on 3GPP specifications. Our main objective in this proposed research wok is to analyze the various packet scheduling algorithms for downlink real time data and present their scheduling metrics. Methods: In this review we considered more recent scheduling algorithms which are QoS aware and with specific focus on real time traffic classes such as VoIP, Video Streaming, Interactive Gaming and mobile video conference. Conclusion: Our most significant observation from this review is that any packet scheduling algorithm for downlink real time data should be QoS aware so that it is readily deployable in the present day multimedia networks. The scheduling schemes should also consider the latest technologies such as Carrier Aggregation (CA) and Multi Input and Multi Output (MIMO). Applications: The presented review will help the researchers and academicians to develop more efficient scheduling schemes for real time applications for smart phone users with better quality of experience and efficient radio resource management.Keywords
LTE-Advanced, Packet Scheduling, QoS, Radio Resource Management, Real Time Traffic- Fuzzy Qualitative Reasoning Model for Astrocytoma Brain Tumor Grade Diagnosis
Abstract Views :191 |
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Authors
Affiliations
1 Department of Computer Science and Engineering, SSN College of Engineering, Chennai – 603110, Tamil Nadu, IN
2 Department of Electronics and Communication Engineering, RMD Engineering College, Chennai – 601206, Tamil Nadu, IN
1 Department of Computer Science and Engineering, SSN College of Engineering, Chennai – 603110, Tamil Nadu, IN
2 Department of Electronics and Communication Engineering, RMD Engineering College, Chennai – 601206, Tamil Nadu, IN
Source
Indian Journal of Science and Technology, Vol 11, No 38 (2018), Pagination: 1-13Abstract
Background: Magnetic Resonance Imaging (MRI) is the most prominently used image acquisition method for brain tumor diagnosis, treatment and research. Objective: In this paper, a fuzzy qualitative reasoning model for diagnosing the grade of Astrocytoma brain tumor using various subtypes of MR images (T1, T1c+, T2, Flair) is explained with its implementation details. Methods: The fuzzy model is implemented in 5 stages namely preprocessing, segmentation, feature extraction, feature selection and building a Fuzzy Inference System (FIS) for diagnosis. In preprocessing, anisotropic filtering is used to remove noise and artifacts whereas the edge information and smoothness are retained. Then the tumor region is segmented by applying active contour method. From the segmented tumor region, textural and shape features are extracted and stored along with the clinical parameters like age, gender and mass effect of the patient for feature selection. The features are analyzed in different dimensions like image, patient, patient with subtype, to determine the sensitive feature subset and its range that discriminates the grade of the tumor. Based on this outcome a Mamdani based fuzzy qualitative reasoning model is built with optimal rule set for tumor grade diagnosis. Findings: The constructed fuzzy model is validated using real data set of MR images and clinical report of patients. The grade of tumor identified is same as that specified in the patient's report and hence the model provides better accuracy. Novelty: The novelty of this research work are: subtypes of MR images with analysis in different dimensions, identification of optimal rule set (minimum number of rules without ambiguity), recognition of irregular shape tumor, suitable model for any knowledge based diagnosis.References
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