Secure digital voting system based on blockchain technology

Electronic voting or e-voting has been used in varying forms since 1970s with fundamental benefits over paper based systems such as increased efficiency and reduced errors. However, there remain challenges to achieve wide spread adoption of such systems especially with respect to improving their resilience against potential faults. Blockchain is a disruptive technology of current era and promises to improve the overall resilience of e-voting systems. This paper presents an effort to leverage benefits of blockchain such as cryptographic foundations and transparency to achieve an effective scheme for e-voting. The proposed scheme conforms to the fundamental requirements for e-voting schemes and achieves end-to-end verifiability. The paper presents details of the proposed e-voting scheme along with its implementation using Multichain platform. The paper presents in-depth evaluation of the scheme which successfully demonstrates its effectiveness to achieve an end-to-end verifiable e-voting scheme

Go-Ethereum for electronic voting system using clique as proof-of-authority

Current advances in information technology have brought about significant changes, including ways to carry out elections using computer technology known as e-voting. Blockchain underlies the popularity of the digital currency Bitcoin and some other digital money, sparking the start of a new era of Internet use, including electronic voting (e-voting) system. In this work, we proposed designing and implementing an evoting system powered by the Ethereum blockchain. We used real-world data from the Indonesian Election Commission (KPU) with 26 candidates and 15,725 voters from the Jelupang sub-district. The testing and evaluation results using three miners in the blockchain show that the system could commit around 23 transactions per second. All 15,725 votes are committed to the blockchain successfully within 12.75 minutes. The total time required for creating all blockchain accounts is 13.4 hours.

E-voting: an immature technology in a critical context

E-voting has been introduced prematurely to national elections in many countries worldwide. There are technical and organizational barriers which must be resolved before the use of e-voting can be recommended in such a critical context. Two fundamental requirements for e-voting systems are in con ict: ballot-secrecy and accuracy. We describe the nature and implications of this conflict, and examine the two main categories of proposed solutions: cryptographic voting schemes, and Voter Veried Audit Trails (VVATs). The conflict may permanently rule out the use of remote e-voting for critical elections, especially when one considers that there is no known way to reproduce the enforced privacy of a voting booth outside the supervision of a polling station. We then examine the difficulty faced by governments when they procure Information and Communication Technology (ICT) systems in general, and some mitigation strategies. We go on to describe some legal implications of the introduction of e-voting, which could have serious consequences if not adequately explored, and discuss the evaluation and maintenance of systems. In the final chapters we explore two approaches to the development of requirements for e-voting

Decoding Information from noisy, redundant, and intentionally-distorted sources

Advances in information technology reduce barriers to information propagation, but at the same time they also induce the information overload problem. For the making of various decisions, mere digestion of the relevant information has become a daunting task due to the massive amount of information available. This information, such as that generated by evaluation systems developed by various web sites, is in general useful but may be noisy and may also contain biased entries. In this study, we establish a framework to systematically tackle the challenging problem of information decoding in the presence of massive and redundant data. When applied to a voting system, our method simultaneously ranks the raters and the ratees using only the evaluation data, consisting of an array of scores each of which represents the rating of a ratee by a rater. Not only is our appraoch effective in decoding information, it is also shown to be robust against various hypothetical types of noise as well as intentional abuses.Comment: 19 pages, 5 figures, accepted for publication in Physica

Enhanced Stegano-Cryptographic Model for Secure Electronic Voting

The issue of security in Information and Communication Technology has been identified as the most critical barrier in the widespread adoption of electronic voting (e-voting). Earlier cryptographic models for secure e-voting are vulnerable to attacks and existing stegano-cryptographic models can be manipulated by an eavesdropper. These shortcomings of existing models of secure e-voting are threats to confidentiality, integrity and verifiability of electronic ballot which are critical to overall success of e-democratic decision making through e-voting.This paper develops an enhanced stegano-cryptographic model for secure electronic voting system in poll-site, web and mobile voting scenarios for better citizens’ participation and credible e-democratic election. The electronic ballot was encrypted using Elliptic Curve Cryptography and Rivest-Sharma-Adleman cryptographic algorithm. The encrypted voter’s ballot was scattered and hidden in the Least Significant Bit (LSB) of the cover media using information hiding attribute of modified LSB-Wavelet steganographic algorithm. The image quality of the model, stego object was quantitatively assessed using Peak Signal to Noise Ratio (PSNR), Signal to Noise Ratio (SNR), Root Mean Square Error (RMSE) and Structural Similarity Index Metrics (SSIM).The results after quantitative performance evaluation shows that the developed stegano-cryptographic model has generic attribute of secured e-voting relevant for the delivery of credible e-democratic decision making. The large scale implementation of the model would be useful to deliver e-voting of high electoral integrity and political trustworthiness, where genuine e-elections are conducted for the populace by government authority. Keywords: Electronic Voting, Cryptography, Steganography, Video, Image, Wavelet, Securit

A BLOCKCHAIN IMPLEMENTATION MODEL FOR ELECTRONIC VOTING SYSTEM

The rate of Blockchain technology adoption is on the increase as seen in the cryptocurrency and Distributed Finance (DiFi) domain. The technology is also attracting lots of attention in many other application areas including the electronic voting(e-voting) system. The electronic voting system is an interesting use case for blockchain technology because critical problems within that space, specifically, the integrity of voting data, the secrecy of the ballot, and a single point of failure can be tackled with the technology. However, the scalability and latency of the blockchain network are two major challenges. This research, therefore, evolves a scalable, latency-improved blockchain implementation model for a Nation-Wide Electronic Voting System. The model is validated by a series of procedures: firstly, data collection, which involves observations, interviews, and the use of secondary data sources. The interview involved five Independent National Electoral Commission (INEC) personnel from the voters' education department and the Information and Communication Technology unit. Secondly, the model was designed using a combination of algorithm, software tools, and design decisions. The design decisions were built on the result of the analysis of four major blockchain networks (Bitcoin, Ethereum, Litecoin, and Dogecoin). Thirdly, the model implementation which is made of the steps taken to develop the proposed model. The implementation method includes setting up the node, creating a private blockchain network, creating a distributed application (DAPP) and the smart contract deployment. The Ethereum Virtual Machine, Solidity, and MongoDB were used to implement the model. The fourth procedure is the evaluation of the model performance from scalability, latency, and usability 99.36 percent improvement on the existing blockchain-based e-voting system; the scalability result shows the proposed model takes an average of 2.6 minutes to spin up a new node; the System Usability Scale (SUS) result shows a usability perception of 76 percent which is above average. The model therefore serves as a novel contribution to the application of blockchain technology to large scale e-voting like national election

State of Alaska Election Security Project Phase 2 Report

A laska’s election system is among the most secure in the country, and it has a number of safeguards other states are now adopting. But the technology Alaska uses to record and count votes could be improved— and the state’s huge size, limited road system, and scattered communities also create special challenges for insuring the integrity of the vote. In this second phase of an ongoing study of Alaska’s election security, we recommend ways of strengthening the system—not only the technology but also the election procedures. The lieutenant governor and the Division of Elections asked the University of Alaska Anchorage to do this evaluation, which began in September 2007.Lieutenant Governor Sean Parnell. State of Alaska Division of Elections.List of Appendices / Glossary / Study Team / Acknowledgments / Introduction / Summary of Recommendations / Part 1 Defense in Depth / Part 2 Fortification of Systems / Part 3 Confidence in Outcomes / Conclusions / Proposed Statement of Work for Phase 3: Implementation / Reference

E-voting in Brazil - the risks to democracy

Literature has shown that countries with strong democratic traditions, such as the United States and Canada, are not yet using electronic voting systems intensively, due to the concern for and emphasis on security. It has revealed that there is no such thing as an error-free computer system, let alone an electronic voting system, and that existing technology does not offer the conditions necessary for a reliable, accurate and secure electronic voting system. In this context, then, what are the risks of e-voting to democracy? In what ways, if at all, can more fragile, less mature democracies be buttressed with e-voting systems? As a key component of e-democracy, it seems that e-voting technologies are to become more secure and increasingly reliable in the near future and will indeed be adopted in many countries. In what ways, if at all, will the introduction of such systems increase voter confidence in the political system, promote citizen engagement in political life, and nurture the evolution of democracy? If both e-voting and edemocracy are emerging based on popular demand - that is, as a demand-driven alternative to current processes, then there is no doubt that they are likely to enhance and improve the efficiency of traditional democracy. However, if e-voting technology is being introduced based on a supply-driven fashion - the technology exists therefore it should and must be implemented - then the implications for democracy should be considered. Brazil's introduction of e-voting offers a cautionary tale of supply-driven technological implication. The purpose of this paper is to demonstrate how the introduction of e-voting in Brazil is highly risky to democracy due to the lack of emphasis on security and the lack of a sociallyinformed and socially driven approach to technological innovation. The Brazilian example illustrates the democratic implications of a market-driven approach. The lack of a technology strategy designed to promote and extend democratic principles is not surprising given the closed door, market-based negotiations that led to the adoption of e-voting in Brazil. The promise, and indeed, the imperative of a democratic, voter-centered approach as an alternative for the development of an electronic voting system, is explored in the paper