CLC number:
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2023-11-06
Cited: 0
Clicked: 934
Citations: Bibtex RefMan EndNote GB/T7714
Xiaolong LIANG, Rui QIN, Juanjuan LI, Fei-Yue WANG. The engineering of circular causality for specialization and design of complex systems: cad2CAS and casCAD2[J]. Frontiers of Information Technology & Electronic Engineering, 2024, 25(2): 323-332.
@article{title="The engineering of circular causality for specialization and design of complex systems: cad2CAS and casCAD2",
author="Xiaolong LIANG, Rui QIN, Juanjuan LI, Fei-Yue WANG",
journal="Frontiers of Information Technology & Electronic Engineering",
volume="25",
number="2",
pages="323-332",
year="2024",
publisher="Zhejiang University Press & Springer",
doi="10.1631/FITEE.2300443"
}
%0 Journal Article
%T The engineering of circular causality for specialization and design of complex systems: cad2CAS and casCAD2
%A Xiaolong LIANG
%A Rui QIN
%A Juanjuan LI
%A Fei-Yue WANG
%J Frontiers of Information Technology & Electronic Engineering
%V 25
%N 2
%P 323-332
%@ 2095-9184
%D 2024
%I Zhejiang University Press & Springer
%DOI 10.1631/FITEE.2300443
TY - JOUR
T1 - The engineering of circular causality for specialization and design of complex systems: cad2CAS and casCAD2
A1 - Xiaolong LIANG
A1 - Rui QIN
A1 - Juanjuan LI
A1 - Fei-Yue WANG
J0 - Frontiers of Information Technology & Electronic Engineering
VL - 25
IS - 2
SP - 323
EP - 332
%@ 2095-9184
Y1 - 2024
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/FITEE.2300443
Abstract: The emergence of decentralized autonomous organizations and operations (DAOs), equipped with innovative mechanisms, enables new possibilities for transforming traditional social collaborative relationships. Mechanisms are the underlying driver for DAOs. However, as a complex system encompassing both social complexity and engineering complexity, DAO mechanisms need to dynamically adapt to the changing external environment. Traditional top-down approaches cannot effectively deal with these problems. The circular causality theory views the operation of complex systems as a continuously evolving dynamic process, providing new perspectives to address these challenges. This paper proposes an engineering methodology grounded in the principles of parallel intelligence and circular causality theory to develop and specialize DAO mechanisms. Computer-aided dynamic design for complex adaptive systems (cad2CAS) is employed to streamline the design of DAO mechanisms and the complex adaptive system for computer-aided dynamic design (casCAD2) is used to verify and guide these mechanisms, thus establishing a causality loop. By proposing this methodology, we aim to enhance the efficiency, security, and adaptability of DAO governance systems, laying the foundation for more robust and resilient decentralized organizations.
[1]Braun A, Häusle N, Karpischek S, 2021. Incentivization in decentralized autonomous organizations. SSRN Electron J.
[2]Chohan UW, 2017. The decentralized autonomous organization and governance issues. SSRN Electron J.
[3]Ding WW, Liang XL, Hou JC, et al., 2021. Parallel governance for decentralized autonomous organizations enabled by blockchain and smart contracts. IEEE 1st Int Conf on Digital Twins and Parallel Intelligence, p.1-4.
[4]Jackson MO, 2014. Mechanism theory. SSRN Electron J.
[5]Jensen JR, von Wachter V, Ross O, 2021. An introduction to decentralized finance (DeFi). Complex Syst Inform Model Quart, 26:150.
[6]Kaal WA, 2021. Decentralized autonomous organizations: internal governance and external legal design. Ann Corp Gov, 5(4):237-307.
[7]Kondova G, Barba R, 2019. Governance of decentralized autonomous organizations. J Mod Account Audit, 15(8):406-411.
[8]Li JJ, Yuan Y, Wang FY, 2021. Blockchain-based digital currency: the state of the art and future trends. Acta Autom Sin, 47(4):715-729 (in Chinese).
[9]Li JJ, Qin R, Wang FY, 2023a. The future of management: DAO to smart organizations and intelligent operations. IEEE Trans Syst Man Cybern Syst, 53(6):3389-3399.
[10]Li JJ, Qin R, Ding WW, et al., 2023b. A new framework for Web3-powered decentralized autonomous organizations and operations. Acta Autom Sin, 49(5):985-998 (in Chinese).
[11]Liang XL, Ding WW, Hou JC, et al., 2021. A comprehensive survey of decentralized autonomous organizations enabled by blockchain and smart contracts. Int J Inform Comput Sci, 2(1):35-48.
[12]Liang XL, Ding WW, Qin R, et al., 2023. From cadCAD to casCAD2: a mechanism validation and verification system for decentralized autonomous organizations based on parallel intelligence. IEEE Trans Comput Soc Syst, early access.
[13]Neftci SN, 2002. Synthetic assets, risk management and imperfections. In: Eatwell J, Taylor L (Eds.), International Capital Markets: Systems in Transition. Oxford University Press, Oxford, UK, p.433-446.
[14]Qin R, Yuan Y, Wang FY, 2020. Blockchain-based knowledge automation for CPSS-oriented parallel management. IEEE Trans Comput Soc Syst, 7(5):1180-1188.
[15]Qin R, Ding WW, Li JJ, et al., 2023. Web3-based decentralized autonomous organizations and operations: architectures, models, and mechanisms. IEEE Trans Syst Man Cybern Syst, 53(4):2073-2082.
[16]Rikken O, Janssen M, Kwee Z, 2019. Governance challenges of blockchain and decentralized autonomous organizations. Inform Polity, 24(4):397-417.
[17]Wang FY, 2004. Parallel system methods for management and control of complex systems. Contr Decis, 19(5):485-489, 514 (in Chinese).
[18]Wang FY, 2010. Parallel control and management for intelligent transportation systems: concepts, architectures, and applications. IEEE Trans Intell Transp Syst, 11(3):630-638.
[19]Wang FY, Qin R, Wang X, et al., 2022a. MetaSocieties in Metaverse: metaEconomics and metaManagement for metaEnterprises and metaCities. IEEE Trans Comput Soc Syst, 9(1):2-7.
[20]Wang FY, Guo JB, Bu GQ, et al., 2022b. Mutually trustworthy human-machine knowledge automation and hybrid augmented intelligence: mechanisms and applications of cognition, management, and control for complex systems. Front Inform Technol Electron Eng, 23(8):1142-1157.
[21]Wang FY, Ding W, Qin R, et al., 2022c. Parallel philosophy for MetaOrganizations with MetaOperations: from Leibniz’s Monad to HanoiDAO. IEEE Trans Comput Soc Syst, 9(3):658-666.
[22]Wang JC, Tang Y, Hare R, et al., 2023. Parallel intelligent education with ChatGPT. Front Inform Technol Electron Eng, early access.
[23]Weyl EG, Ohlhaver P, Buterin V, 2022. Decentralized society: finding Web3’s soul. SSRN Electron J.
[24]Yuan Y, Zeng D, 2012. Co-evolution-based mechanism design for sponsored search advertising. Electron Commer Res Appl, 11(6):537-547.
[25]Yuan Y, Wang FY, 2018. Blockchain and cryptocurrencies: model, techniques, and applications. IEEE Trans Syst Man Cybern Syst, 48(9):1421-1428.
[26]Zeigler BP, Praehofer H, Kim TG, 2000. Theory of Modeling and Simulation (2nd Ed.). Academic Press, San Diego, USA.
[27]Zhang ZX, Zargham M, Preciado VM, 2020. On modeling blockchain-enabled economic networks as stochastic dynamical systems. Appl Netw Sci, 5(1):19.
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