Precision Photonics for the Most Demanding Applications
Ultra-High-Resolution Photonic Interrogation
Aerospace & Space Optics
Ultra-high-resolution strain sensing detects nanostrain-level deformations in satellites and precision telescope mirrors. Continuous monitoring maintains optical alignment and enables predictive maintenance.
Semiconductor Manufacturing
Ultra-high-resolution sensing enables nanometer-scale positioning and real-time strain mapping in lithography and wafer stages. Continuous feedback supports sub-nanometer precision and die-level stress analysis, improving yield.
Quantum & Cryogenic Systems
High-sensitivity sensing enables precise temperature stabilization in dilution refrigerators and superconducting qubits. Millikelvin-level resolution is achieved without electromagnetic interference, supporting operation.
Battery & Energy Research
In-situ sensing monitors mechanical expansion and thermal gradients during battery charge and discharge cycles. Real-time insight into microscopic deformation reveals early degradation mechanisms and dendrite formation.
Infrastructure Monitoring
Microstrain-level sensing tracks structural deformation in bridges, tunnels, and dams. Early detection of fatigue and stress accumulation enables predictive maintenance years before visible damage occurs.
Material Science & Physics
Nanostrain-resolution measurements capture lattice deformation and phase transitions in advanced materials. This extends metrology limits for next-generation materials and superconducting systems.
Photonic Precision
Nanostrain and millikelvin sensing
Ardeonics develops and manufactures ultra-high-resolution photonic interrogators and sensors for nanostrain-level deformation and millikelvin-scale temperature measurement in industrial and research environments. With 100× higher resolution than conventional FBG solutions, our systems enable insight and control where every femtometer and millikelvin matter.
Wavelength-Based Sensing
Optical shifts into strain and temperature
Ardeonics converts strain and temperature changes into precise optical wavelength shifts using Fiber Bragg Grating (FBG) technology. Our photonic interrogators resolve these shifts with femtometer-level precision by integrating Photonic Integrated Circuits with FBG, Ring Resonator, or Distributed Bragg Reflector sensors, eliminating electrical noise and ensuring stable, accurate measurements in radiation-rich, cryogenic, and electromagnetically sensitive environments.
Applications & R&D
Cardiovascular Health Monitoring
Thermal Mapping Solution
MilliKelvin Temperature Variations
100× higher resolution
than standard FBG interrogation systems
Fully optical architecture
with complete immunity to electromagnetic interference
PIC-integrated design
delivering exceptional stability and scalability
Real-time measurement
with continuous acquisition up to 100 Hz per channel
Proven performance
across demanding environments