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The project targeted the following performance metrics:
(i) lower operational temperature (<100°C);
(ii) reduced transmission losses (<25%);
(iii) achieve a more uniform alignment;
(iv) lower drive voltage (<50V);
(v) ensure mechanical stability and recovery of the alignment.
The key achievement was the development of a state-of-the-art mixture that meets the following requirements:
(i) Operational temperatures from 30°C - 45°C;
(ii) Reduced transmission losses to <15% using new alignment process;
(iii) Achieved a more uniform alignment using appropriate electric field conditions;
(iv) State-of-the-art mixture exhibits voltages >50V due to presence of polymer, non-polymer mixtures exhibit lower voltages;
(v) Recovery of the alignment and stability to laser powers of 2W
This mixture combines speed with lower temperature operation and full 2Pi phase. It can be polymerized to make the device rugged, withstands thermal cycling and exposure to UV light. Tests with the non-polymerizable mixture demonstrated resilience to high laser powers and exhibits <15% transmission losses (8% of which come from Fresnel reflection losses from the glass substrates). This could be reduced further using a reflective device geometry combined with anti-reflection coatings. For the state-of-the-art mixture, the drive voltages have exceeded the 50 V targeted, which is due to the presence of the polymer network.
Optical beam steering enables motionless pointing of light. The lack of mechanical moving parts not only reduces overall Mass, Volume, and Power (MVP) to a fraction of conventional solutions, but also reduces the associated risk due to friction fatigue. Moreover, actuator vibrations are completely eliminated, enabling Space interferometric experiments that were previously not possible. The applications of this technology both on Earth and in Space are only beginning to be fully understood and realised.
In the context of telecommunications, the need for steerable beams has become the latest commercial frontier for market advantage allowing for communications channels to be differentiated spatially as well as time/frequency.
In the context of LIDAR, leading public, military, and private organizations have shown interest in reduced MVP LIDAR for Space, automotive and airborne applications.
Technologies proposed include solid-state optical phased arrays, piezoelectric mirrors, diffractive optics, and liquid crystal spatial light modulators (SLM). MDSRL, in partnership with the University of Oxford (UoO), are proposing to develop a novel liquid crystal (LC) technology tailored specifically to SLMs for Space applications. Researchers from the Department of Engineering Science at Oxford are pioneering new beam-steering technology based on the development of novel fast-switching LC modes that target frame rates which exceed 1 kHz whilst maintaining analogue control and full 2 modulation of the optical phase.
This technology has the potential to enable a range of applications including Space telecommunications, space navigation, situational awareness, interferometry, and exploration.
