DECENTRALIZED PLATFORM FOR FINANCING CHARITY PROJECTS
Iryna Segeda
National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute» (Ukraine)
Vladyslav Kotsiuba
National Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute" (Ukraine)
Oleksii Shushura
National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute» (Ukraine)
Viktoriia Bokovets
Vinnytsia National Technical University (Ukraine)
Natalia Koval
koval@vntu.edu.uaVinnitsa National Technical University (Ukraine)
Aliya Kalizhanova
University of Power Engineering and Telecommunications (Kazakhstan)
Abstract
The rapid development of new technologies, together with the emergence of new military conflicts and humanitarian crises, creates the need for quick response and the introduction of new methods of effective assistance to the affected population and the restoration of damaged territories. Decentralized charity became one of these methods of assistance. To implement the task, the latest technologies were used, which combine maximum transparency and complete security when forming and working with charitable payments. The main technologies that were used: blockchain and smart contracts on it, protocols of liquidity pools and profitable farming, as well as web development technologies for creating a web application. The research analyzed existing approaches, methods of software solutions for financing decentralized charity; developed and improved the mathematical model and architecture of the software application. A system of smart contracts was created using additional administrative modules, and on its basis, a decentralized charitable platform for assistance to Ukraine was implemented in the form of a web application. Such a decentralized system can be freely used and implemented nowadays to finance the most necessary charitable projects of our country with crypto-assets in various spheres: humanitarian, social or in matters of security and weapons.
Keywords:
Charity, decentralization, blockchain, smart contract, decentralized finance, liquidity pool, staking, web platformReferences
[1] Azarova A.: Information Technologies and Neural Network Means for Building the Complex Goal Program "Improving the Management of Intellectual Capital". Lecture Notes on Data Engineering and Communications Technologies 77, 2022, 534–547.
DOI: https://doi.org/10.1007/978-3-030-82014-5_36
Google Scholar
[2] ERC-20: Token Standard. Ethereum Improvement Proposals [https://eips.ethereum.org/EIPS/eip] (available: 20.02.2024).
Google Scholar
[3] Gervais A. et al.: On the Security and Performance of Proof of Work Blockchains. ACM SIGSAC Conference on Computer and Communications Security – CCS'16 10, 2016, 3–16.
DOI: https://doi.org/10.1145/2976749.2978341
Google Scholar
[4] Hileman G. M.: Rauchs Global cryptocurrency benchmarking study. Cambridge, 2017, 95–101.
DOI: https://doi.org/10.2139/ssrn.2965436
Google Scholar
[5] How Uniswap works. Uniswap Documentation [https://docs.uniswap.org/contracts/v2/concepts/protocol-overview/how-uniswap-works] (available: 20.02.2024).
Google Scholar
[6] Karmanska Y.: During the full-scale war, the sums of Ukrainian donations increased ninefold – research. Forbes, 2022 [https://forbes.ua/news/za-chas-povnomasshtabnoi-viyni-sumi-pozhertv-ukraintsiv-zrosli-v-devyat-raziv-doslidzhennya-09082022-7571] (available: 20.02.2024).
Google Scholar
[7] Mamyrbayev O. et al.: Mathematical Model and Method of Enterprise Financial Risk Assessment Based on Threshold Elements. CEUR Workshop Proceedings 3101, 2021, 300–313.
Google Scholar
[8] Segeda I. V., Kotsyuba V. O.: Development and decentralization of charity during the war in Ukraine. Discussions for the improvement of science. II International Scientific and Practical Conference, 2023, 293–297 [https://eu-conf.com/ua/events/discussions-for-the-improvement-of-science/].
Google Scholar
[9] Tapscott D., Tapscott A.: Blockchain revolution. How the technology underlying Bitcoin and other cryptocurrencies is changing the world Lviv. Litopys, 2019, 492.
Google Scholar
[10] The incredible math in Ethereum staking contract (and how to implement it in solidity) [https://medium.com/coinmonks/the-incredible-math-in-ethereum-staking-contract-and-how-to-implement-it-in-solidity-e8f8d973ea1f].
Google Scholar
[11] The Decentralized Charity Ecosystem [https://medium.com/givecrypto/the-decentralized-charity-ecosystem-8cf8eaea7b21] (available: 20.02.2024).
Google Scholar
[12] Vovchak O. D. et al.: Payment systems Kyiv. Znannia, 2008.
Google Scholar
[13] What Is Uniswap? A Complete Beginner’s Guide [https://www.coindesk.com/business/2021/02/04/what-is-uniswap-a-complete-beginners-guide/] (available: 20.02.2024).
Google Scholar
[14] Yurchenko D. Cryptocurrencies and Charity: How to Make and Collect Donations in Digital Assets. 2023 [https://incrypted.com/kriptovalyuty-i-blagotvoritelnost/] (available: 20.02.2024).
Google Scholar
Authors
Iryna SegedaNational Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute» Ukraine
Authors
Vladyslav KotsiubaNational Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute" Ukraine
Authors
Oleksii ShushuraNational Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute» Ukraine
Authors
Viktoriia BokovetsVinnytsia National Technical University Ukraine
Authors
Aliya KalizhanovaUniversity of Power Engineering and Telecommunications Kazakhstan
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