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The stars look very different today

Building eyes for independent rovers, satellites, and explorers. Equipped with space-grade visual awareness and the modular infrastructure for the new space age.

Deliver space-grade edge processing, turn cameras into autonomous reasoning modules

1

Features

FPGA-based parallel architecture enables collision avoidance, precision docking, and autonomous navigation without Earth's input.

2

Features

Extended operational endurance means more science, longer missions, and reliable performance in the power-constrained space.

3

Features

Radiation-hardened components and environmental resilience ensure predictable performance in the harshest conditions imaginable. Stay autonomous even during comms blackout.

4

Features

Start with core vision processing, keep adding scientific instrument guidance, or autonomous capabilities. It's a modular platform with a proven space-ready backbone.

situational awareness
(SSA)

AI vision systems and autonomous intelligence that makes complex missions possible

Low Earth orbit has become the busiest highway in the solar system, with over 34,000 tracked objects larger than a softball racing overhead at 17,500 miles per hour. Your high-speed visual processing can simultaneously track dozens of approaching objects, calculate collision probabilities in real-time, and execute onboard classification and trajectory computations with no human-in-the-loop.

RENDEZVOUS & docking

Centimeter-level precision at orbital velocity

On-board visual approach algorithms transform high-stakes maneuvers into routine operations, enabling automated cargo transfers, structural assembly, and crew/uncrewed coordination. This level of autonomous precision is essential for safe, efficient orbital operations.

visual navigation

Have a confident, adaptive journey

Enable rovers to navigate autonomously by recognizing landmarks, tracking star fields, and adapting trajectories in real-time without waiting for Earth's instructions. Perform challenging high-stake tasks like visual odometry and real-time terrain analysis to identify safe paths, hazardous obstacles, and scientifically valuable targets. All processed locally.

Need your own integration?

Build your own space-grade sensor in five steps with our blueprints and prequalified industrial components

Month 1

conceptual design

Defining the Blueprint

Preliminary requirements of the device, including its functionality, performance metrics, and integrations. Share yours or choose from our selection of designs to save around 6 months of initial R&D.

Month 3

prototype development

Building the Proof of Concept

A functional model to test the design, identify potential issues, and validate its performance in a lab environment.

Month 7

design refinement

Optimizing for compliance, certification and stability

Refining the design based on a feedback loop from prototyping and precise specification requirements.

Month 9

testing

Hardening and finalizing the design

Assess the device’s ability to withstand launch vibrations, extreme thermal vacuums, and electromagnetic interference. Additionally, validate its resilience against radiation to ensure durability for the duration of the mission, provided the orbit.

Month 12

integration

The Final Build-Out

The final manufacturing of the device, integrating it with the chassis, and conducting thorough final tests. Documentation and design artifacts handover.

DISCUSS YOUR REQUIREMENTS

Supporting the Pathfinders

Proud to partner with the brightest minds who never settle and keep pushing the frontier