KYC Optimization using Blockchain Smart Contract Technology

— In the present scenario, it is vital for any organization, especially the financial organizations, to understand customers and their financial dealings better. KYC is a process to verify identity and related details of corresponding customers. The current KYC mechanism has a severe concern in financial institutions as it requires separate ledger for the separate financial organizations. Every institution has its KYC process, which sometimes may include third-party, which may cause increased maintenance cost, time and redundancy. There is considerable wastage of costs in the form of opportunity cost, maintenance cost, customer verification cost and many more of around $27 million according to an economic survey. The current KYC process is very time-consuming, and it decreases the user experience. We have proposed an enhanced KYC system using blockchain technology to improve the existing KYC system. An inherent feature of the DLT is used to remove the third-party involvement, and smart contracts are used to build our logic in the mobility of the data. Blockchain technology has various types of cryptographic security which provide a safer place to transact over an unsecured channel. Using the facility of DLT, cryptography and consensus mechanism of blockchain, the proposed model of KYC process can optimize storing, updating, sharing of data and accessing operations along with enhanced security, transparency and privacy. It also enhances customer ownership and improves customer experience. It not only reduces the time duration and document update problem but also saves opportunity cost, aggregation, cost, maintenance cost and many more costs, which can affect the performance of any organization.

[1]  Alexandros Psychas,et al.  Know Your Customer (KYC) Implementation with Smart Contracts on a Privacy-Oriented Decentralized Architecture , 2020, Future Internet.

[2]  Bilal Farooq,et al.  A multi-layered blockchain framework for smart mobility data-markets , 2019, Transportation Research Part C: Emerging Technologies.

[3]  Alexander Mense,et al.  Security Vulnerabilities in Ethereum Smart Contracts , 2018, iiWAS.

[4]  Zibin Zheng,et al.  Blockchain challenges and opportunities: a survey , 2018, Int. J. Web Grid Serv..

[5]  José Parra Moyano,et al.  KYC Optimization Using Distributed Ledger Technology , 2017, Business & Information Systems Engineering.

[6]  Marko Vukolic,et al.  The Quest for Scalable Blockchain Fabric: Proof-of-Work vs. BFT Replication , 2015, iNetSeC.

[7]  Marc Pilkington,et al.  Blockchain Technology: Principles and Applications , 2015 .

[8]  Ariel Gabizon,et al.  Cryptocurrencies Without Proof of Work , 2014, Financial Cryptography Workshops.

[9]  Miguel Castro,et al.  Practical byzantine fault tolerance and proactive recovery , 2002, TOCS.

[10]  Karan Singh,et al.  Comparative Analysis of Consensus Algorithms of Blockchain Technology , 2020 .

[11]  Karan Singh,et al.  Comparative Analysis of Consensus Algorithms and Issues in Integration of Blockchain with IoT , 2020 .

[12]  José Parra Moyano,et al.  Optimised and dynamic KYC system based on blockchain technology , 2019, International Journal of Blockchains and Cryptocurrencies.

[13]  C. Jaag,et al.  Blockchain Technology and Cryptocurrencies: Opportunities for Postal Financial Services , 2017 .

[14]  S. Nakamoto,et al.  Bitcoin: A Peer-to-Peer Electronic Cash System , 2008 .