A Unified Trust Architecture for Secured Voting Systems and a Hedge Against Inflation: An Advanced Framework Towards Sustainable Blockchains

Muhammad Muzammal Farooq; Nasir Ayub; Umair Ghafoor; Asfar Ali; Hamayun Khan; Salheen Bakhet; Majid Ali Ali

doi:10.62019/wrk70h63

Authors

Muhammad Muzammal Farooq Faculty of Computer Science & IT, Superior University Lahore, 54000, Pakistan.
Nasir Ayub Deputy Head of Engineering Calrom Limited, M16EG, United Kingdom.
Umair Ghafoor Deputy Head of Engineering Calrom Limited, M16EG, United Kingdom.
Asfar Ali Information Technology Department of LHC, and with the Department of Information Technology, Superior University Lahore, 54000, Pakistan.
Hamayun Khan Department of Computer Science, Faculty of Computer Science & IT, Superior University Lahore, 54000, Pakistan.
Salheen Bakhet Department of Computer Science, University of Engineering and Technology, Lahore, Pakistan.
Majid Ali Ali Tec Joints Block G3 Phase 2 Johar Town, Lahore, 54600, Pakistan.

DOI:

https://doi.org/10.62019/wrk70h63

Keywords:

Blockchain, Voting Systems, Inflation Hedge, Trust Architecture, Cryptographic Verification, Decentralized Governance, Scarcity Mechanism, Electoral Integrity, Monetary Credibility, Distributed Consensus.

Abstract

The dual crises of electoral integrity and monetary stability share a common cause: the loss of trust in centralized systems. This paper develops a unified approach for the study of blockchain-based systems for trust, verification, and scarcity logic in two domains: voting systems and inflation hedging. By analyzing the properties of blockchain-based systems for trust, verification, and scarcity logic, we show that blockchain enables the transition from trust-based to verification- based systems. In voting systems, blockchain-based systems offer cryptographic verification for the integrity of voting outcomes without compromising ballot secrecy through the use of advanced cryptography. In monetary systems, blockchain-based systems offer transparent scarcity logic and verification for the constraints imposed by the monetary supply. Our analysis, however, reveals the limitations of blockchain-based voting systems for coercion resistance and the limitations of blockchain-based monetary assets for long-term credibility. The unified approach identifies the components of trust architecture for identity, recording, verification, coordination, and governance as key determinants for the success of blockchain-based systems. The comparative analysis reveals that the key benefit of blockchain-based systems is not the properties of the system but the ability to distribute trust among verification mechanisms. We develop a conceptual model for the design of hybrid systems for the integration of blockchain-based verification and institutional systems. The unified approach contributes to the literature on blockchain by providing tools for the evaluation of blockchain-based systems for various applications in the domains of governance and economics.