This article traces the evolution of escape rooms through the case of the Titanic Escape Room, framed as a cyber-physical system in which architecture, firmware, and hardware solutions are subordinated to the task of creating an invisible fail-safe technological substrate for an immersive experience. The study is relevant because the Location-Based Entertainment (LBE) industry is developing rapidly, determining success not through isolated puzzles but by sustaining a cinematic, plausible, and uninterrupted narrative. The article demonstrates that an experience-centric model replaces puzzle-centric design in this context. Through the application of cyber-physical systems theory and HCI principles, combined with fault-tolerant design, this work is novel due to its thorough engineering analysis of the Titanic system. The article proposes a distributed three-tier architecture (COGS server, Raspberry Pi media servers, Arduino nodes). This approach justifies its choice, also justifying the selection of communication protocols and failover strategies. Also examined in detail is the article's analysis of three engineering solutions: adaptive Morse-code decoder, hardware printer redundancy, and hybrid PCM/MP3 audio playback. These are interpreted as manifestations of a unified strategy of engineering for time and reliability, aimed at minimizing latency and covertly eliminating faults, which are preconditions for preserving immersion. The main findings underscore that immersiveness in LBE systems is a reproducible outcome achieved by strict adherence to real-time principles, adaptive interface design, and multilayer redundancy. The article will be helpful to researchers of cyber-physical systems, entertainment-technology engineers, HCI specialists, and developers of immersive LBE projects.

cyber-physical systems, Location-Based Entertainment, immersion, architecture, firmware, distributed systems, fault tolerance

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