Amit Kumar
Department of Computer Science, National University, Gazipur, Bangladesh

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Enhancing Transparency in Decision-Making Systems Using Explainable Artificial Intelligence Models Amit Kumar; Raisul Khan; Md. Rashid; Antu Roy
The Eastasouth Journal of Information System and Computer Science Vol. 1 No. 02 (2023): The Eastasouth Journal of Information System and Computer Science (ESISCS)
Publisher : Eastasouth Institute

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58812/esiscs.v1i02.1073

Abstract

The increasing reliance on artificial intelligence (AI) in decision-making systems has raised critical concerns regarding transparency, interpretability, and trust. Many advanced AI models, particularly deep learning techniques, operate as opaque “black-box” systems, making it difficult for users to understand how decisions are derived. This lack of explainability limits user confidence, hinders accountability, and poses ethical and regulatory challenges. This study addresses these issues by exploring the role of Explainable Artificial Intelligence (XAI) in enhancing transparency in decision-making systems. The research is conceptually supported by three key stages illustrated in the figures. First, opaque AI systems are examined, highlighting the limitations of black-box models that provide output without meaningful explanations. Second, an XAI framework is introduced, demonstrating how interpretability techniques such as feature importance analysis, rule-based reasoning, and model-agnostic explanation methods can reveal the internal logic of AI systems. These techniques enable users to understand the reasoning behind predictions, thereby improving system interpretability. Third, the study presents the outcome of integrating XAI into decision-making processes, emphasizing transparent and accountable systems that foster trust, fairness, and user engagement. A comparative methodological approach is adopted, evaluating both traditional black-box models and explainable models using interpretability and performance metrics. The findings indicate that while there may be trade-offs between accuracy and interpretability, the inclusion of XAI significantly enhances user understanding and trust in AI-driven decisions. In conclusion, this study demonstrates that explainable AI plays a vital role in transforming opaque decision-making systems into transparent and accountable frameworks. By bridging the gap between complex algorithms and human understanding, XAI supports the development of trustworthy and ethically aligned AI systems suitable for real-world applications.
Design and Implementation of Secure and Scalable Distributed Computing Systems for Modern Applications Partha Sarothi; Zulfiqur Rahman; Amrita Khan; Amit Kumar; Kamal Khan
The Eastasouth Journal of Information System and Computer Science Vol. 2 No. 02 (2024): The Eastasouth Journal of Information System and Computer Science (ESISCS)
Publisher : Eastasouth Institute

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58812/esiscs.v2i02.1074

Abstract

The rapid growth of modern applications, including cloud computing, big data analytics, and Internet of Things (IoT), has significantly increased the demand for secure and scalable distributed computing systems. Traditional centralized architecture is no longer sufficient to handle large-scale data processing and dynamic workloads, leading to the adoption of distributed computing paradigms. This study presents the design and implementation of a secure and scalable distributed computing framework, supported by performance evaluation through analytical figures illustrating system scalability, resource utilization, latency, and security effectiveness. The analysis demonstrates that distributed architectures significantly improve system scalability by enabling horizontal scaling and efficient workload distribution across multiple nodes. The figures highlight that as the number of nodes increases; system throughput improves while latency is reduced through optimized communication and load balancing mechanisms. Additionally, the implementation of advanced security protocols, including encryption, authentication, and access control, enhances system resilience against cyber threats. The results further indicate that the integration of containerization and orchestration technologies, such as Kubernetes, improves resource utilization and system reliability. Security evaluation metrics show a reduction in vulnerability exposure and improved threat detection capabilities in distributed environments. However, the figures also reveal challenges related to network latency and resource management, particularly in highly dynamic environments.