A breakthrough computational AI technology by UltraCoolAI.
Our water-based optical AI system is a fusion of natural ice crystal structures with advanced photonics. Promising unparalleled computational capabilities while championing energy efficiency and environmental sustainability; a new era in adaptive, high-capacity optical AI computing.
Intricately structured ice crystals form the foundation of an adaptable neural network, capable of processing information using light.
We use four orthogonal properties of light - intensity, color, polarization, and phase - for dense data encoding, the system projects intricate light patterns onto custom-grown ice crystals, enabling sophisticated information processing.
The intricate ice crystal lattice guides light through unique 3D structures, processing all it properties using refraction, scatter, birefringence and geometry. There's even potential for quantum interactions.
Light interacting with the unique arrangement of crystals performs billions of simple computational operations in parallel. Each crystal, akin to neuronal structures in a biological brain, processes data in a specific way based on its structure and composition.
Processed light is decoded as it exits the ice structure and captured as digital data. This output represents the result of the system’s highly complex and sophisticated computational structure. All at the speed of light.
Water structures are self-healing and reconfiguration due to their fluid nature, able to respond to changes or damage.
Water is an abundant and environmentally friendly material offering energy-efficient, inexpensive, safe and sustainable computing.
Bespoke 3D ice structures are seeded using template fabrication - using laser ablation or photolithography techniques to create microscopic patterns on a substrate (e.g., silicon or sapphire) that act as templates for desired ice crystal growth.
The crystal lattice's complex pathways replicate neural connectivity. Light intensities and polarization states mimic synaptic weights and neural activations. Birefringence and non-linear optical properties within the crystals provide the crucial non-linear neural activation functions.