Our Technology
Cutting-edge optical technologies powering the future
Hyperspectral Imaging
Hyperspectral imaging combines advanced imaging and spectroscopy to capture both spatial detail and rich spectral information from a scene or object. By analysing how materials interact with light across hundreds of narrow wavelength bands, this technology reveals insights far beyond what conventional imaging can provide.
Today, hyperspectral imaging is a proven and powerful tool across a wide range of industries — from agriculture and manufacturing to environmental monitoring,
forensics, medical diagnostics, and cultural heritage conservation — enabling more accurate detection, identification, and decision-making.
True snapshot hyperspectral imaging captures full 3D spatial and spectral data in a single exposure—no scanning required.
Real-time performance enables accurate imaging of fast-moving scenes without motion blur or stitching artefacts.
Compact, robust, and vibration-resistant design with no moving parts, ideal for deployment on drones and autonomous platforms.
Simple camera-like operation delivers advanced hyperspectral capability with ease of integration.
FTNIR Interferometric Spectrometer
By removing moving components, the system achieves exceptional robustness, stability, and vibration tolerance, while significantly reducing size, weight, and power consumption. This enables reliable spectral measurements in dynamic or mobile platforms where traditional instruments are impractical.
The non-scanning approach enables rapid spectral acquisition, supporting real-time or near–real-time analysis without compromising spectral resolution or sensitivity. Combined with its compact form factor, the technology is well suited for applications in field spectroscopy, industrial monitoring, environmental sensing, and embedded analytical systems.
This next-generation FTNIR architecture delivers laboratory-grade spectral performance in a rugged, integration-friendly form—bringing high-precision infrared spectroscopy beyond the lab and into real-world deployment.
True snapshot operation enables rapid spectral acquisition without mechanical scanning, improving reliability and temporal resolution.
Compact and rugged design with no moving parts, offering high resistance to vibration and environmental disturbances.
High spectral fidelity comparable to conventional FTIR systems, while significantly reducing system size and complexity.
Integration-ready platform suited for field deployment, embedded sensing, and real-time analytical applications.
Advanced Optical Systems for Airborne & Space
Advanced Earth observation imaging systems for airborne and low-Earth-orbit platforms are engineered to deliver high-resolution, high-fidelity data for demanding operational environments. Designed for precision and reliability, these systems integrate advanced optics, sensors, and electronics to support detailed Earth monitoring, mapping, and situational awareness across a wide range of mission profiles.
High-resolution imaging performance optimized for airborne and orbital operation, enabling accurate and information-rich Earth observation.
Tailor-designed system architecture, allowing full control over key parameters such as centre of gravity, structural layout, material selection, electronics architecture, and component grading.
Mission-specific optimisation, enabling the system to be engineered around platform constraints, environmental conditions, and performance requirements.
Robust and flight-proven design approach, ensuring reliable operation under vibration, thermal variation, and long-duration mission conditions.