The revolutionary underwater single photon imaging system (USPIS) project will develop next generation technology and equipment capable of delivering wide area coverage and high-resolution 3D images in all underwater environments.
The consortium brings together decades of expertise and experience from six key industrial, research and academic institutions with world-class backgrounds to collaboratively develop a commercially viable subsea mapping system and consists of:
- Sonardyne International Ltd — with over 50 years expertise in the provision of underwater positioning, sensing, and imaging systems; we are leading the project, system integration and testing.
- Fraunhofer UK Research Ltd — are developing the laser system and environmental testing.
- RedWave Labs Ltd — are designing and building the rugged and compact control electronics for the 100 pico-second pulsed laser source.
- Photon Force Ltd — are developing a next-generation 1D SPAD array sensor and accompanying FPGA for onboard processing targeted at imaging through scattering environments.
- Heriot-Watt University — are applying their knowledge to the design of the transceiver system and single-photon imaging techniques, building on their extensive research and utilising their test facilities.
- University of Edinburgh — are bringing their experience in designing SPADs for 3D imaging and assisting Heriot-Watt University in evaluating these SPADs in an underwater setting, to help inform the design of the bespoke SPAD sensor and the imaging system.
The project will deliver a subsea mapping system using innovative single photon array detector technology, combined with a laser producing extremely short and high-power pulses of light. The system is intended for deployment on a subsea vehicle and will generate 3D maps at high altitude above the sea floor.
Current sonar and laser imaging technology is limited by water clarity, range and amount of light. However, this project will apply single photon imaging detection technology to generate highly detailed images even in low light, murky water and from greater altitude above the sea floor.
This new approach differs from other techniques as it relies on state-of-the-art single photon avalanche diode (SPAD) detection technologies, which allow for three-dimensional imaging even with extremely low levels of light returning through distance or turbid water. The system will operate at altitudes and speeds well beyond those which current optically based systems are capable of.
High resolution 3D maps are needed for an increasing number of important subsea applications. Uses include the installation and operation of offshore wind farms, oil and gas rig decommissioning, environmental monitoring and security operations. The demand for ever more detailed seabed information will only increase as the world continues to become more environmentally aware and uses cleaner energy sources.
The project has been running for two years and testing of the prototype equipment will start in April 2024.
Quotes from consortium members.
“We are delighted to be leading this consortium of world-class experts and contributing our expertise in developing the next generation of underwater mapping and imaging. The possibilities that this ground-breaking technology will open up are breath-taking and we cannot wait to see it in action.” – Darryl Newborough, Technical Director, Sonardyne International Ltd.
“We are hugely excited to be part of this project; single-photon LIDAR systems are already in use in ground-based, air-borne and space-borne applications, and we look forward to exploiting their potential in underwater imaging too.” – Istvan Gyongy, Lecturer, University of Edinburgh
“We are thrilled to work with such an accomplished consortium of partners providing a path to solving complex real-world problems. The new 1D array family of sensors Photon Force is developing for this project will enable formerly unattainable standards of sub-sea vision as well as opening up other diverse applications.” – Richard Walker, CEO, Photon Force
“We are looking forward to starting testing in a few months. We have been working on this project for several years now and it is very exciting to finally see quantum detection technologies integrated on an underwater vehicle.” – Aurora Maccarone, Assistant Professor, Heriot Watt University