Abstract : In this paper, we propose a novel logistic regression-based framework for classifying nodes in Internet of Things (IoT) networks as either trusted or blackhole nodes. The model leverages multiple behavioral features of nodes, including packet delivery ratio, packet loss, energy efficiency, responsiveness, cooperation, and reliability. These features are linearly combined using model coefficients and processed through a sigmoid function to yield a probability score between 0 and 1. Based on a predefined threshold, nodes are classified as trusted if the probability exceeds the threshold, and as blackhole nodes otherwise. A detailed mathematical example is provided to illustrate the implementation of the model. To evaluate its effectiveness, the proposed framework is tested under simulated IoT network conditions, and its performance is analyzed using key metrics such as packet delivery ratio, packet loss, end-to-end delay, detection accuracy, and routing overhead. Results demonstrate that the model efficiently identifies malicious nodes and enhances overall network reliability and security, offering a lightweight and effective solution for real-time threat detection in resource-constrained IoT environments.. Full article
Abstract : Social media platforms are crucial spaces for discussing mental health issues. They can provide support systems but also act as risk factors for individuals experiencing distress. This paper proposes a system utilizing Bidirectional Encoder Representations from Transformers (BERT) to classify Reddit posts into mental health categories such as bipolar disorder, depression, anxiety, suicide, and others. The classifier is trained on posts collected from relevant subreddits, with preprocessing and feature extraction handled using NLP techniques. The results demonstrate the feasibility of using BERT-based models for classifying mental health indicators from text data. Furthermore, the paper proposes an application where social media platforms subtly adjust users’ feeds to promote positive content when signs of mental health distress are detected.. Full article
Abstract : This paper focuses on 150KW induction furnace employed with a reconfigured Series Resonant Converter (SRC) under faulty conditions. Resonant converter topologies have been popular for a few years in high-power transmission viz. medical, biotechnology, nuclear fusion. This network design is frequently utilized in solid-state transducers, where fault tolerance is an important feature that may be achieved through redundancy. Fault tolerance is an important element of power applications since it makes the system more reliable and available. A critical feature of any fault tolerance topology is the early detection of faults and their rectification or prevention. There are a variety of fault-tolerant topologies available in industry; however most of them rely on redundancy, which raises the cost and maintenance work. In an application with little or minimal redundancy, there is still room for improvement in terms of failure tolerance. The goal of the suggested topology is to increase efficiency while decreasing redundancy. It is frequently designed to accomplish converter fault tolerance by resetting the network during each failure, which may weaken the converter's performance but stops it from working. For example, induction furnaces are frequently used in a variety of industrial processes, including waste energy generation, metal melting, welding, and hardening. because fault-resistant topologies and high power under all circumstances are necessary for these jobs. Reconfiguration of the circuit under faulty conditions is examined in this project, so that a full bridge under faulty conditions is reconfigured as a half bridge for specialized applications such as an induction furnace, etc.. Full article