4K Video, Images, Infrastructure Inspection and Analysis.
Micro Drone (<250g) Class Operations requiring less permitting, we are able to operate where larger systems can't.
Analysis of client mission needs, performance requirements, operational objectives and maintenance capabilities in order to determine an appropriate set of systems to build a capable UAS fleet for commercial applications. Development of operational best practices, flight safety culture, CONOPS and test program design.
Analysis of technical data of UAS payload options, including synthetic aperture radar (SAR), Optical Wide Area Search Sensor, Communications Relay, EO/IR Turrets, and AIS receivers.
Market Analysis of Class 1 and Class 2, VTOL UAS, and preparation of briefing notes for senior staff, and management.
Market Analysis of UAS Payloads, including Synthetic Aperture Radar, Electro-Optical/Infrared Imaging Sensors, Wide Area Search Sensors, AIS Transponders, and other novel systems to determine the technology readiness level of proposed payload systems.
Support infrastructure requirements, design and analysis, Flight Test Program design, concepts of operations, crew role analysis and more.
Competition Rules Analysis, and definition of requirements for Unmanned Rescue Flyer.
Market Analysis of UAS subsystems, and trade study to determine best approach for deign and integration of UAS sensors, subsystems, and payload subsystems.
AI Object recognition, aircraft control and autonomous navigation.
Development of Pre-Flight Checklist, Start-up, Run-up, and Shutdown procedures for test vehicles.
RPAS certification effort, worked with Transport Canada to obtain a SFOC for the aerial vehicle. This included preparation of a SORA, and manufacturer’s declaration per CAR 901.76, and Standard 922-RPAS Safety Assurance.
FAA certification of a large RPAS in the United States, obtaining an N-number registration, via Form 8130-6, and 14 CFR Part 21.
Design, planning and coordination of Field Test plan for incremental performance testing of RPAS systems.
Team Lead of the Maritime Helicopter Project (MHP) Training Devices Hardware Team, responsible for the design, documentation and maintenance planning of Helicopter Crew Trainers and Mission Simulators at CFB Shearwater, CFB Patricia Bay, Electronic Warfare Hot Bench at Shirley’s Bay, and the GDMS-C Development Lab in Ottawa. Additionally responsible for the design, build, and installation of the CR 2.1 upgrade kits for the deployed helicopter crew trainers, to update the trainers configuration to better match that of the CH-148 helicopter after its CR 2.1 Mission Systems upgrade.
Experimental investigations to develop C-UAS technologies, best practices, and operational security.
Equipment teardown, components analysis for vulnerability detection.
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