DESIGN AND IMPLEMENTATION OF AN ADVANCED ROBOTIC PLATFORM FOR AUTOMATED IMMUNO-HEMATOLOGY ANALYSIS
Keywords:
Immuno-hematology Automation, Robotic Biomedical Instrumentation, Multi-platform Integration, AI-driven Temperature Control, Cross-protocol Communication SystemsAbstract
This article presents an innovative approach to robotic biomedical instrumentation designed specifically for immuno-hematology analysis, integrating cutting-edge technologies while maintaining compliance with medical quality standards and FDA requirements. This article incorporates a sophisticated B2B multi-tier software architecture supported by MS Sync Framework Services, combining motion control, firmware, and driver components for precise robotic operations. The implementation features an intranet-based assay script scheduling system enhanced by AI-driven temperature control using fuzzy logic and machine learning algorithms. The comprehensive architecture encompasses real-time robotics control, advanced software hardware interfacing, and robust network communications via multiple protocols. A key innovation is the integration of a Zoom Lens Camera Control System operating across various platforms, complemented by a multi-axis rotary control system utilizing stepper motors and linear encoders. The system leverages diverse programming environments and frameworks, demonstrating compatibility across multiple operating systems. This integrated approach represents a significant advancement in automated immuno-hematology analysis, offering enhanced precision, improved operational efficiency, and robust reliability for clinical applications.
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