An Integrated Thresholding and Morphological Process with Histogram-based Method for Brain Tumor Analysis and MRI Tumor Detection

Q2 Computer Science

EAI Endorsed Transactions on Pervasive Health and Technology Pub Date : 2024-03-21 DOI:10.4108/eetpht.10.5498

A. R. Deepa, M. Chaurasia, Peram Sai, Harsha Vardhan, Ganishetti Ritwika, Mamillapalli Samanth Kumar, Yaswanth Chowdary Nettm

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Abstract

INTRODUCTION: Over the past several years analysis of image has moved from larger system to pervasive portable devices. For example, in pervasive biomedical systems like PACS-Picture achieving and Communication system, computing is the main element. Image processing application for biomedical diagnosis needs efficient and fast algorithms and architecture for their functionality. Future pervasive systems designed for biomedical application should provide computational efficiency and portability. The discrete wavelet transform (DWT) designed in on-chip been used in several applications like data, audio signal processing and machine learning. OBJECTIVES: The conventional convolution based scheme is easy to implement but occupies more memory , power and delay. The conventional lifting based architecture has multiplier blocks which increase the critical delay. Designing the wavelet transform without multiplier is a effective task especially for the 2-D image analysis. Without multiplier Daubechies wavelet implementation in forward and inverse transforms may find efficient. The objective of the work is on obtaining low power and less delay architecture. METHODS: The proposed lifting scheme for two dimensional architecture reduces critical path through multiplier less and provides low power, area and high throughput. The proposed multiplier is delay efficient. RESULTS: The architecture is Multiplier less in the predict and update stage and the implementation carried out in FPGA by the use of Quartus II 9.1 and it is found that there is reduction in consumption of power at approximately 56%. There is reduction in delay due to multiplier less architecture. CONCLUSION: multiplier less architecture provides less delay and low power. The power observed is in milliwatts and suitable for high speed application due to low critical path delay.

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基于直方图的脑肿瘤分析和磁共振成像肿瘤检测阈值化和形态学处理集成方法

简介：在过去几年中，图像分析已从大型系统转向普及型便携设备。例如，在 PACS（图像实现与通信系统）等普及型生物医学系统中，计算是主要元素。用于生物医学诊断的图像处理应用需要高效、快速的算法和架构来实现其功能。为生物医学应用设计的未来普适系统应提供计算效率和可移植性。在芯片上设计的离散小波变换（DWT）已被用于数据、音频信号处理和机器学习等多个应用领域。目标：传统的基于卷积的方案易于实现，但占用更多内存、功耗和延迟。传统的基于提升的架构有乘法器块，这会增加临界延迟。设计不带乘法器的小波变换是一项有效的任务，尤其是在二维图像分析中。不使用乘法器的多贝希斯小波实现正向和反向变换可能会很有效。这项工作的目标是获得低功耗、低延迟的架构。方法：针对二维架构提出的提升方案通过减少乘法器来减少关键路径，并提供低功耗、低面积和高吞吐量。提议的乘法器具有延迟效率。结果：该架构在预测和更新阶段减少了乘法器，并使用 Quartus II 9.1 在 FPGA 中进行了实现，发现功耗降低了约 56%。由于采用了少乘法器架构，延迟也有所减少。结论：少乘法器架构提供了更少的延迟和更低的功耗。观察到的功耗单位为毫瓦，由于关键路径延迟低，适合高速应用。

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