JITA
JITA Journal of Information Technology and Applications
This paper introduces Marquise 57, an innovative architectural framework for autonomous robotic systems, implemented and validated on the UNTLab 3327 mobile platform. Inspired by the mathematical symmetry and refractive properties of the Marquise diamond cut, the architecture employs a dual-core deconvolution strategy to eliminate logical blind spots and systemic latency.
The framework conceptualizes the robot as a digital organism, with operations divided into two cognitive layers: the Crown (Core 1), responsible for high-precision motion control via EncoMotors, and the Pavilion (Core 0), dedicated to environmental awareness through the SiLog (Sensor Information Log) protocol. At the center of this architecture is the Tower, a hardware-encrypted vault utilizing military-grade AES-256 algorithms to ensure forensic integrity of mission data.
Experimental validation over a verified distance of 1,089.57 meters demonstrates near-zero latency execution and bit-perfect forensic reconstruction of environmental events. By transforming physical stimuli into coherent informational structures, the Marquise 57 architecture establishes a robust blueprint for mission-critical cyber-physical systems operating in complex realworld environments.
This paper introduces Marquise 57, an innovative architectural framework for autonomous robotic systems, implemented and validated on the UNTLab 3327 mobile platform. Inspired by the mathematical symmetry and refractive properties of the Marquise diamond cut, the architecture employs a dual-core deconvolution strategy to eliminate logical blind spots and systemic latency.
The framework conceptualizes the robot as a digital organism, with operations divided into two cognitive layers: the Crown (Core 1), responsible for high-precision motion control via EncoMotors, and the Pavilion (Core 0), dedicated to environmental awareness through the SiLog (Sensor Information Log) protocol. At the center of this architecture is the Tower, a hardware-encrypted vault utilizing military-grade AES-256 algorithms to ensure forensic integrity of mission data.
Experimental validation over a verified distance of 1,089.57 meters demonstrates near-zero latency execution and bit-perfect forensic reconstruction of environmental events. By transforming physical stimuli into coherent informational structures, the Marquise 57 architecture establishes a robust blueprint for mission-critical cyber-physical systems operating in complex realworld environments.
This paper introduces Marquise 57, an innovative architectural framework for autonomous robotic systems, implemented and validated on the UNTLab 3327 mobile platform. Inspired by the mathematical symmetry and refractive properties of the Marquise diamond cut, the architecture employs a dual-core deconvolution strategy to eliminate logical blind spots and systemic latency.
The framework conceptualizes the robot as a digital organism, with operations divided into two cognitive layers: the Crown (Core 1), responsible for high-precision motion control via EncoMotors, and the Pavilion (Core 0), dedicated to environmental awareness through the SiLog (Sensor Information Log) protocol. At the center of this architecture is the Tower, a hardware-encrypted vault utilizing military-grade AES-256 algorithms to ensure forensic integrity of mission data.
Experimental validation over a verified distance of 1,089.57 meters demonstrates near-zero latency execution and bit-perfect forensic reconstruction of environmental events. By transforming physical stimuli into coherent informational structures, the Marquise 57 architecture establishes a robust blueprint for mission-critical cyber-physical systems operating in complex realworld environments.