The advancements in the field of information technology in recent years have been very influential in affecting all domains that can utilize the power of data analysis for making decisions. Such domains that have been seeing new ideas implemented in their conventional methods are that of education and training. The advent of Internet of Things (IoT) has made monitoring and tracking of data very efficient. Data can come from a variety of sources, from wearables to smart class objects. To unlock the true potential from this technology, educators are urged to introduce IoT in their curriculum to help speed up the process. In this study, the various studies in the fields of wearables in education, vocational training, medicinal training, Green IoT and Smart City are reviewed. The implementations of Machine Learning (ML) in IoT are also explored, proving its viability in tasks such as bunching and classification. However, even with the abundant studies in the fields of IoT and education, its successful implementations are relatively scarce, thus bottlenecking current research.
The method of huge integrating involves implementing a significant transistor count in an extremely condensed space. Combinatorial logic has shown to be particularly effective in quantum computing as well as other designing applications. In VLSI design, the primary goal is to cut down on power consumption as well as latency. For the purpose of establishing technology and supporting the increased use of electrical machines, it is vital to decrease sub-threshold current flowing for large strains. This research explores the feasibility of implementing a shift register and without the Multi-threshold CMOS (MTCMOS) approach. At the process technology of 0.18 µm, 0.12 µm, and 90 nm, an investigation into the power loss and transmission delay characteristics of a variety of flip-flops is carried out. As technology gets shrunk, the amount of power lost through leakage rises. Using the greatest technique among all run time strategies, namely MTCMOS, helps to limit the amount of power lost due to leakage. The purpose of this article is to give a comparison between various traditional flip-flops and the TSPC flip-flop with regard to power usage, diffusion delays, product of delay-power (PDP), area, and power flow using the findings obtained from the Microwind simulator.
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