传感器网络云物联网能量优化的智能泛在计算模型

IF 0.6 Q4 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Deepa S.N.
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This study aims to improve the network quality and improve the data accuracy rate during the network transmission process using the developed ubiquitous deep learning computational model.\n\n\nDesign/methodology/approach\nIn this research study, a novel intelligent ubiquitous machine learning computational model is designed and modelled to maintain the optimal energy level of cloud IOTs in sensor network domains. A new intelligent ubiquitous computational model that learns with gradient descent learning rule and operates with auto-encoders and decoders to attain better energy optimization is developed. A new unified deterministic sine-cosine algorithm has been developed in this study for parameter optimization of weight factors in the ubiquitous machine learning model.\n\n\nFindings\nThe newly developed ubiquitous model is used for finding network energy and performing its optimization in the considered sensor network model. At the time of progressive simulation, residual energy, network overhead, end-to-end delay, network lifetime and a number of live nodes are evaluated. It is elucidated from the results attained, that the ubiquitous deep learning model resulted in better metrics based on its appropriate cluster selection and minimized route selection mechanism.\n\n\nResearch limitations/implications\nIn this research study, a novel ubiquitous computing model derived from a new optimization algorithm called a unified deterministic sine-cosine algorithm and deep learning technique was derived and applied for maintaining the optimal energy level of cloud IOTs in sensor networks. The deterministic levy flight concept is applied for developing the new optimization technique and this tends to determine the parametric weight values for the deep learning model. The ubiquitous deep learning model is designed with auto-encoders and decoders and their corresponding layers weights are determined for optimal values with the optimization algorithm. The modelled ubiquitous deep learning approach was applied in this study to determine the network energy consumption rate and thereby optimize the energy level by increasing the lifetime of the sensor network model considered. 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引用次数: 2

摘要

目的:在以往的研究中开发的模型遇到的局限性是出现了全球极小值;为此,本研究开发了一种新的智能泛在计算模型,该模型采用梯度下降学习规则进行学习,并与自编码器和自解码器一起工作,以达到更好的能量优化。泛在机器学习计算模型过程比常规的监督学习或无监督学习计算模型使用深度学习技术更好地执行训练,从而为基于云的物联网(iot)的问题领域提供更好的学习和优化。本研究旨在利用开发的泛在深度学习计算模型提高网络质量,提高网络传输过程中的数据准确率。设计/方法/方法在本研究中,设计并建模了一种新的智能泛在机器学习计算模型,以保持传感器网络域中云物联网的最佳能量水平。提出了一种新的智能泛在计算模型,该模型采用梯度下降学习规则进行学习,并与自编码器和自解码器协同工作,以达到更好的能量优化。本文提出了一种新的统一的确定性正弦-余弦算法,用于泛在机器学习模型中权重因子的参数优化。在考虑的传感器网络模型中,使用新开发的泛在模型寻找网络能量并进行优化。在渐进式仿真时,对剩余能量、网络开销、端到端延迟、网络生存时间和活动节点数量进行了评估。结果表明,泛在深度学习模型基于适当的聚类选择和最小化的路由选择机制获得了更好的度量。在本研究中,推导了一种新的泛在计算模型,该模型由一种新的优化算法(称为统一确定性正弦-余弦算法)和深度学习技术衍生而来,并应用于保持传感器网络中云物联网的最佳能量水平。本文将确定性征费飞行的概念应用于新的优化技术的开发,该技术倾向于确定深度学习模型的参数权值。采用自编码器和自解码器设计泛在深度学习模型,并通过优化算法确定其对应层的最优权值。本研究采用建模的泛在深度学习方法来确定网络能耗率,从而通过增加所考虑的传感器网络模型的寿命来优化能量水平。对于所有考虑的网络度量,普适计算模型已被证明比早期研究中的先前方法更有效和通用。基于深度学习技术的泛在计算模型可以应用于任何类型的云辅助物联网,包括无线传感器网络、自组织网络、无线接入技术网络、异构网络等。实际上,所开发的模型有助于计算任何考虑的网络模型的云物联网的最佳能量水平,这有助于保持更好的网络生命周期并减少网络的端到端延迟。社会意义提出的研究的社会意义是,它有助于减少能源消耗,并增加基于云物联网的传感器网络模型的网络寿命。这种方法可以帮助广大用户以最小的能量消耗获得更好的传输速率,也可以减少传输延迟。在本研究中,使用机器学习模型作为一种泛在计算系统,对云辅助物联网传感器网络模型的网络优化进行建模和分析。泛在计算模型与机器学习技术开发智能系统,增强用户做出更好、更快的决策。在通信领域,使用机器学习创建的预测和优化模型加速了确定问题解决方案的新方法。考虑到学习技术的重要性,泛在计算模型基于深度学习策略进行设计,学习机制自适应以获得更好的网络优化模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Intelligent ubiquitous computing model for energy optimization of cloud IOTs in sensor networks
Purpose Limitations encountered with the models developed in the previous studies had occurrences of global minima; due to which this study developed a new intelligent ubiquitous computational model that learns with gradient descent learning rule and operates with auto-encoders and decoders to attain better energy optimization. Ubiquitous machine learning computational model process performs training in a better way than regular supervised learning or unsupervised learning computational models with deep learning techniques, resulting in better learning and optimization for the considered problem domain of cloud-based internet-of-things (IOTs). This study aims to improve the network quality and improve the data accuracy rate during the network transmission process using the developed ubiquitous deep learning computational model. Design/methodology/approach In this research study, a novel intelligent ubiquitous machine learning computational model is designed and modelled to maintain the optimal energy level of cloud IOTs in sensor network domains. A new intelligent ubiquitous computational model that learns with gradient descent learning rule and operates with auto-encoders and decoders to attain better energy optimization is developed. A new unified deterministic sine-cosine algorithm has been developed in this study for parameter optimization of weight factors in the ubiquitous machine learning model. Findings The newly developed ubiquitous model is used for finding network energy and performing its optimization in the considered sensor network model. At the time of progressive simulation, residual energy, network overhead, end-to-end delay, network lifetime and a number of live nodes are evaluated. It is elucidated from the results attained, that the ubiquitous deep learning model resulted in better metrics based on its appropriate cluster selection and minimized route selection mechanism. Research limitations/implications In this research study, a novel ubiquitous computing model derived from a new optimization algorithm called a unified deterministic sine-cosine algorithm and deep learning technique was derived and applied for maintaining the optimal energy level of cloud IOTs in sensor networks. The deterministic levy flight concept is applied for developing the new optimization technique and this tends to determine the parametric weight values for the deep learning model. The ubiquitous deep learning model is designed with auto-encoders and decoders and their corresponding layers weights are determined for optimal values with the optimization algorithm. The modelled ubiquitous deep learning approach was applied in this study to determine the network energy consumption rate and thereby optimize the energy level by increasing the lifetime of the sensor network model considered. For all the considered network metrics, the ubiquitous computing model has proved to be effective and versatile than previous approaches from early research studies. Practical implications The developed ubiquitous computing model with deep learning techniques can be applied for any type of cloud-assisted IOTs in respect of wireless sensor networks, ad hoc networks, radio access technology networks, heterogeneous networks, etc. Practically, the developed model facilitates computing the optimal energy level of the cloud IOTs for any considered network models and this helps in maintaining a better network lifetime and reducing the end-to-end delay of the networks. Social implications The social implication of the proposed research study is that it helps in reducing energy consumption and increases the network lifetime of the cloud IOT based sensor network models. This approach helps the people in large to have a better transmission rate with minimized energy consumption and also reduces the delay in transmission. Originality/value In this research study, the network optimization of cloud-assisted IOTs of sensor network models is modelled and analysed using machine learning models as a kind of ubiquitous computing system. Ubiquitous computing models with machine learning techniques develop intelligent systems and enhances the users to make better and faster decisions. In the communication domain, the use of predictive and optimization models created with machine learning accelerates new ways to determine solutions to problems. Considering the importance of learning techniques, the ubiquitous computing model is designed based on a deep learning strategy and the learning mechanism adapts itself to attain a better network optimization model.
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来源期刊
International Journal of Pervasive Computing and Communications
International Journal of Pervasive Computing and Communications COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-
CiteScore
6.60
自引率
0.00%
发文量
54
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