SHA-CNN:用于边缘人工智能的可扩展分层感知卷积神经网络

Narendra Singh Dhakad, Yuvnish Malhotra, Santosh Kumar Vishvakarma, Kaushik Roy
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摘要

本文介绍了面向边缘人工智能应用的可扩展分层感知卷积神经网络(SHA-CNN)模型架构。所提出的分层 CNN 模型经过精心设计,在计算效率和准确性之间取得了平衡,从而应对了资源受限的边缘设备所带来的挑战。SHA-CNN 的准确度与最先进的分层模型不相上下,同时在准确度指标上优于基线模型,从而证明了它的功效。其关键创新在于模型的分层意识,使其能够在多个抽象层次上识别并优先处理相关特征。所提出的架构以分层的方式对数据进行分类,有助于深入理解数据集中的复杂特征。此外,SHA-CNN 还具有显著的可扩展性,可以无缝地纳入新的类别。这种灵活性在动态环境中尤为有利,因为在这种环境中,模型需要适应不断变化的数据集,并容纳更多的类别,而无需进行大量的重新训练。测试结果表明,MNIST、CIFAR-10 和 CIFAR-100 数据集的准确率分别为 99.34%、83.35% 和 63.66%。对于 CIFAR-100,我们提出的架构在执行分层分类时减少了 10% 的计算量,而准确率与最先进架构相比仅降低了 0.7%。SHA-CNN 对 FPGA 架构的适应性凸显了它在计算资源有限的边缘设备中部署的潜力。因此,SHA-CNN 框架是分层 CNN、可扩展性和基于 FPGA 的边缘人工智能交叉领域的一个有前途的进步。
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SHA-CNN: Scalable Hierarchical Aware Convolutional Neural Network for Edge AI
This paper introduces a Scalable Hierarchical Aware Convolutional Neural Network (SHA-CNN) model architecture for Edge AI applications. The proposed hierarchical CNN model is meticulously crafted to strike a balance between computational efficiency and accuracy, addressing the challenges posed by resource-constrained edge devices. SHA-CNN demonstrates its efficacy by achieving accuracy comparable to state-of-the-art hierarchical models while outperforming baseline models in accuracy metrics. The key innovation lies in the model's hierarchical awareness, enabling it to discern and prioritize relevant features at multiple levels of abstraction. The proposed architecture classifies data in a hierarchical manner, facilitating a nuanced understanding of complex features within the datasets. Moreover, SHA-CNN exhibits a remarkable capacity for scalability, allowing for the seamless incorporation of new classes. This flexibility is particularly advantageous in dynamic environments where the model needs to adapt to evolving datasets and accommodate additional classes without the need for extensive retraining. Testing has been conducted on the PYNQ Z2 FPGA board to validate the proposed model. The results achieved an accuracy of 99.34%, 83.35%, and 63.66% for MNIST, CIFAR-10, and CIFAR-100 datasets, respectively. For CIFAR-100, our proposed architecture performs hierarchical classification with 10% reduced computation while compromising only 0.7% accuracy with the state-of-the-art. The adaptability of SHA-CNN to FPGA architecture underscores its potential for deployment in edge devices, where computational resources are limited. The SHA-CNN framework thus emerges as a promising advancement in the intersection of hierarchical CNNs, scalability, and FPGA-based Edge AI.
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