Real-Time Payment Orchestration and Fraud Governance Framework: Cloud-Native Treasury Optimization with Ensemble Deep Learning Integration
DOI:
https://doi.org/10.32628/CSEIT25113583Keywords:
Multi-rail payment orchestration, Treasury digitization, Ensemble deep learning, Fraud governance, Cloud-native architecture, Distributed ledger technology, Receivables accelerationAbstract
The exponential growth of digital payment ecosystems has created unprecedented challenges in payment orchestration, fraud detection, and treasury management across heterogeneous financial networks. Contemporary banking systems struggle with fragmented payment rails, inadequate real-time fraud governance, and limited integration between physical and digital liquidity channels, resulting in operational inefficiencies and elevated fraud exposure. This research introduces an intelligent cloud-native treasury digitization framework that synthesizes multi-rail payment orchestration, accelerated receivables processing, hybrid cash logistics, and layered fraud governance through ensemble deep learning architectures deployed on distributed cloud infrastructure. The proposed architecture integrates Real-Time Payment networks, Automated Clearing House systems, wire transfer protocols, remote deposit platforms, and physical cash management into a unified orchestration layer governed by convolutional and recurrent neural networks with blockchain-enabled smart contracts for immutable audit trails. Experimental validation demonstrates 99.1% fraud detection accuracy, 34% cost reduction in routing optimization, 47% improvement in liquidity velocity, and 78% reduction in manual exception handling. This research establishes a comprehensive paradigm for enterprise-scale treasury modernization combining artificial intelligence, distributed computing, and financial network integration.
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