Development of an integrated control and actuation system for a multi-axis turret launcher platform. The system combines servo-driven mechanisms, embedded control units, and real-time feedback sensors to achieve precise targeting, stabilization, and safety interlocks.

Designed for defense applications, the solution delivers high accuracy and responsiveness under demanding operational conditions — demonstrating ENGIMAX’s strength in control systems, electronics, and mechatronic integration. 

A fully integrated control and stabilization system designed for precision targeting and remote operation of mounted weapon systems. The RCWS incorporates high-performance motor drives, advanced control algorithms, and multi-sensor feedback loops to ensure accurate line-of-sight stabilization under dynamic conditions.

Developed with embedded real-time processing and modular architecture, the system supports customizable configurations for various calibers and platforms — delivering reliability, safety, and operational efficiency in demanding defense environments. 

Comprehensive refurbishment and life-extension of the OKA-E1 and OKA-Complex missile test systems. This project involved reverse engineering, control system redevelopment, electronic component restoration, and recalibration of measurement units to restore full operational capability.

By integrating modern diagnostics and control hardware, the systems were upgraded to meet current technical and safety standards — ensuring continued reliability and accuracy for defense testing operations.  

ACMI stands for Air Combat Maneuvering Instrumentation. It is a high-performance airborne tracking and telemetry system designed for real-time flight data monitoring and post-mission analysis. The system integrates GPS/INS sensors, embedded processing, and wireless communication to capture precise flight dynamics and engagement data throughout training missions.

Developed for defense and aerospace applications, the ACMI pod provides accurate, synchronized data for debriefing, performance evaluation, and tactical development — ensuring mission realism and operational insight. 

Development of an integrated guidance and control solution for precision munition applications. The system employs sensor fusion, navigation algorithms, and closed-loop control to deliver accurate terminal guidance while enforcing strict safety, authorization, and fault-management protocols. Built on a modular architecture, the solution includes mission planning, secure communications, and post-mission data logging for performance assessment. 

All development and testing were conducted in controlled, authorized environments with an emphasis on compliance, fail-safe design, and operator accountability.  

Development of an integrated, AI-based asset management system designed to manage the complete asset lifecycle through intelligent data processing and analytics. The system combines real-time asset inventory and tracking with machine learning–driven analysis to improve decision accuracy, operational efficiency, and overall asset visibility.

The platform performs contextual asset search and data analysis across multiple data sources, transforming asset information into structured insights that support operational monitoring and planning. Predictive analytics are applied to forecast procurement requirements, identify risks related to asset degradation or stock shortages, and recommend optimal maintenance and replacement schedules based on usage patterns and historical performance data.

In addition, the system supports automated asset performance reporting, KPI evaluation, and compliance monitoring through comprehensive digital activity logging. This enables traceability, audit readiness, and centralized oversight of asset condition, value, and utilization — providing a reliable decision-support foundation for complex operational environments.  

Custom-built equipment designed to support university research and experimental studies. Developed projects include a 6-Component External Balance System for aerodynamic testing, an Oven Curing System for composite material processing, and an Equal Channel Angular Pressing (ECAP) Machine for metallurgical research.

Each unit was tailored in collaboration with academic teams, integrating precise control, sensing, and automation for reliable, repeatable results. 

Integrated surveillance solutions developed across coastal, aerial, and ocean domains. Projects include electro-optical coastal monitoring systems, UAV-mounted imaging payloads such as the EO1000 UAV Camera and Retina SRS2000, and satellite-monitored buoys for real-time ocean data transmission.

Each system integrates sensing, control, and communication technologies to deliver continuous situational awareness and reliable field performance.  

At ENGIMAX, we believe innovation thrives through collaboration. Our diverse portfolio demonstrates how engineering excellence and client trust create outcomes that perform in the field and stand the test of time.