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RESILIENCE ENGINEERING PARADIGMS FOR FINANCIAL SYSTEM UPTIME DURING VOLATILITY: A SOCIO-TECHNICAL SYSTEMS PERSPECTIVE

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Dr. Mateo Alvarez-Santos 1 ,
4 Universidad de Chile, Santiago, Chile

Abstract

The accelerating digitization and global interconnection of financial markets have dramatically increased both the efficiency and fragility of modern financial systems. Volatile market conditions, cyber-physical interdependencies, algorithmic trading, and globally distributed infrastructures have created environments in which even minor disturbances can propagate rapidly into systemic disruptions. Within this context, the concept of resilience engineering—originally developed in safety-critical domains such as aviation, nuclear power, and aerospace—has emerged as a powerful analytical and design framework for ensuring sustained operational performance under conditions of stress, surprise, and uncertainty. This study develops a comprehensive resilience-engineering-based model for understanding and improving uptime in financial systems during periods of extreme volatility. Drawing on socio-technical systems theory, organizational safety science, and risk management scholarship, it situates financial infrastructures within a broader landscape of adaptive capacity, organizational culture, technological complexity, and human decision-making (Hollnagel, 2004; Woods, 2006).

Methodologically, the research employs an interpretive, literature-driven analytical design that synthesizes insights across engineering, cognitive science, organizational theory, and risk analysis. Instead of quantitative modeling, the study uses conceptual triangulation to identify recurring patterns of resilience erosion and recovery, drawing on documented experiences from complex engineered systems (Pate-Cornell, 1990; Pate-Cornell & Fischbeck, 1994). Through this approach, the article reveals that financial system uptime during volatility is shaped less by isolated technical safeguards and more by the coherence of organizational sense-making, the flexibility of control structures, and the capacity to reconfigure resources in real time (Mendoça & Wallace, 2006).

Ultimately, this article contributes a theoretically grounded, interdisciplinary model of financial resilience that extends beyond conventional notions of stability and robustness. By embedding financial infrastructures within a socio-technical resilience framework, it offers both scholars and practitioners a deeper understanding of how sustained uptime can be engineered, governed, and cultivated in an era of unprecedented volatility

Keywords

Financial resilience, resilience engineering, system uptime, socio-technical systems

References

📄 Aviation Safety Network. (1992). Accident description: Airbus A320-111.
📄 Zarboutis, N., & Wright, P. (2006). Using complexity theories to reveal emerged patterns that erode the resilience of complex systems.
📄 Dasari, H. (2025). Resilience engineering in financial systems: Strategies for ensuring uptime during volatility. The American Journal of Engineering and Technology, 7(7), 54–61. https://doi.org/10.37547/tajet/Volume07Issue07-06
📄 Jackson, S. (2002). Organizational safety: A systems engineering perspective.
📄 Boroditsky, L. (2011). How languages construct time.
📄 Leveson, N. (1995). Safety-critical computer systems. Addison-Wesley.
📄 Pate-Cornell, E. (1990). Organizational aspects of engineering system safety: The case of offshore platforms. Science, 250(4985), 1210–1217.
📄 Westrum, R. (2006). A typology of resilience situations.
📄 Madni, A. M., Madni, C. C., & Salasin, J. (2002). ProACT™: Process-aware zero latency system for distributed, collaborative enterprises.
📄 Eyles, D. (2004). Tales from the lunar module guidance computer.
📄 Alexander, C. (1964). Notes on the synthesis of form. Harvard University Press.
📄 NASA Mars Climate Orbiter Web Site. (2000).
📄 Vaughan, D. (1996). The Challenger launch decision. University of Chicago Press.
📄 Anderson, R. J. (2008). Security engineering—A guide to building dependable distributed systems (2nd ed.). Wiley.
📄 Beyer, H., & Holtzblatt, K. (1998). Contextual design: Defining customer-centered systems. Morgan Kaufmann.
📄 Conrow, E. H. (2000). Effective risk management: Some keys to success.
📄 Mendoça, D., & Wallace, W. A. (2006). Adaptive capacity: Electric power restoration in New York City following the 11 September 2001 attacks.
📄 Pate-Cornell, E., & Fischbeck, P. S. (1994). Risk management for the tiles of the space shuttle.
📄 Hollnagel, E. (2004). Barriers and accident prevention. Ashgate.
📄 Woods, D. (2006). Essential characteristics of resilience.
📄 NTSB. (2000). Aircraft accident report: In-flight breakup over the Atlantic Ocean, Trans World Airline Flight 800.
📄 BEA. (n.d.). Report on 25 July 2000 at Patte d’Oie in Gonesse (95) to the Concorde registered at F-BTSC.
📄 Atance, C. M., & O’Neill, D. K. (2001). Episodic future thinking. Trends in Cognitive Sciences, 5(12), 533–537.

How to Cite

Dr. Mateo Alvarez-Santos. (2025). RESILIENCE ENGINEERING PARADIGMS FOR FINANCIAL SYSTEM UPTIME DURING VOLATILITY: A SOCIO-TECHNICAL SYSTEMS PERSPECTIVE. Global Multidisciplinary Journal, 4(12), 82-91. https://www.grpublishing.org/journals/index.php/gmj/article/view/279

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