Automated token launchpads are increasingly adopted as on-chain infrastructures for large-scale asset deployment, yet they are commonly analyzed at the level of individual smart contracts or isolated token events. Such perspectives obscure the fact that contemporary launchpads often operate as distributed, automated systems composed of multiple factories, proxy contracts, orchestrators, and ephemeral operational wallets. As a result, event-level observability frequently diverges from the underlying structural organization of the system. This work presents a forensic case study of the Virtual Protocol, reconstructing its token launch infrastructure as a deterministic and repeatable deployment pipeline. Through transaction-level analysis and bottom-up architectural reconstruction across thousands of deployment events, we identify a recurring sequence of operations encompassing contract creation, liquidity pair instantiation, approval flows, liquidity provisioning, and subsequent abandonment of operational wallets. The analysis further documents the systematic use of ephemeral, script-generated wallets, the presence of multiple functionally related factory instances—including secondary and undocumented factories—and the use of proxy patterns and near-identical bytecode variants to fragment attribution and observability. By comparing multiple launches, we derive a behavioral fingerprint of the protocol based on transaction ordering, call structure, temporal patterns, and wallet–contract relationships. This fingerprint enables the identification of launches attributable to the same underlying infrastructure even in the absence of explicit branding or direct linkage, and allows differentiation between native deployments and structurally distinct imitations. The study does not assess intent, exploitability, or economic outcomes. Instead, it adopts a structural, system-level perspective, highlighting how automation and architectural fragmentation introduce noise, opacity, and inferential asymmetries not captured by conventional contract-level audits. By articulating these findings as transferable structural patterns, this case study contributes to blockchain forensics, threat intelligence, and risk-oriented analysis of automated launchpad infrastructures in event-centric blockchain environments. This work is released as a working paper and has not undergone formal peer review.
Manuele Tele junior Fernandez (Wed,) studied this question.