Efficient data handling in smart healthcare using Quotient Hash Trees and gaussian hilbert regression

Efficient data handling in smart healthcare using Quotient Hash Trees and gaussian hilbert regression

Significant amounts of heterogeneous medical data are developed daily from several medical devices, and sensor data analysis across IoT domains is becoming challenging. The conservative data warehouses possess the potential to integrate data and support interactive data exploration. However, transfe...

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Bibliographic Details
Main Authors: T. Kalai Selvi, S. Sasirekha
Format: Article
Language:English
Published: Elsevier 2025-09-01
Series:Ain Shams Engineering Journal
Subjects:
Heterogeneous Medical Data
Gaussian Replicating
Kernel Hilbert
Quotient Hash Tree
Data Management Server
Internet of Things
Online Access:http://www.sciencedirect.com/science/article/pii/S2090447925002941
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Summary:Significant amounts of heterogeneous medical data are developed daily from several medical devices, and sensor data analysis across IoT domains is becoming challenging. The conservative data warehouses possess the potential to integrate data and support interactive data exploration. However, transferring data with minimum loss and storing it in a unified format is arduous and time-consuming. The proposed Gaussian Replicating Hilbert Regression and Quotient Hash Tree (GRHR-QHT) method is introduced to convert heterogeneous data into a unified format with improved accuracy and reduced time. The proposed GRHR-QHT performs three processes: data collection, transfer, and storage. At first, linear acceleration and angular velocity-based vector data collection are transmitted to the data management server. The collected data are stored in the input matrix. The data management server constructs multiple data into a unified format without any loss using GRH-based sequencing. This data management server reduces variance among aspect spaces through minimum distance with empirical organizations of samples. Also, the Polynomial Regression function is used to determine the relationship between the independent parameters. Then, unified data gets stored in the data management server using a Quotient Hash Tree (QHT) for easy access and less space complexity. The experimental assessment of the GRHR-QHT technique and existing methods is compared with different metrics: accuracy, time, error rate, space complexity, throughput, packet delivery ratio, service availability, reliability, response time, and end-to-end delay. The outcome of the suggested method is compared with conventional techniques in terms of improved 11% accuracy and 36% throughput with 33%, 41%, and 20% minimum time, error rate, and space complexity.
ISSN:2090-4479

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