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We drive the future of human
machine interaction with scientific
innovation.
machine interaction with scientific
innovation.
Two Technical Limits
Breaking Free from Isolation
VR builds immersion by isolating the user, closed optical paths that seal you from your environment. Suitable for workplace simulation, but awkward for daily use.
Beyond the Limits of a Lens
Even the most advanced headsets are still tiny head-mounted displays, far from lifelike clarity.
The core architecture: Enabling Real-World Holography
CubeVi pioneers an open optical system — a new class of display architecture that fuses optics, computation, and perception. Three hardware-software co-evolution technologies form the foundation of this transformation.
TECHNOLOGY 1
Hardware-Accelerated Adaptive Light Field Coupling
Photon emission is dynamically reconfigured by hardware logic, bypassing GPU latency and achieving sub-millisecond parallax stability across open optical space.
TECHNOLOGY 2
Multimodal Fusion Spatial Holographic Stability Engine
Global photometric sensing, frame-locked optics, and motion foresight algorithms ensure that every photon arrives exactly when and where the observer perceives it.
TECHNOLOGY 3
Hybrid-Rate Opto-Computational Pipeline
Scene geometry and photonic rendering execute in dual asynchronous cycles, collapsing serial latency into a unified holographic response loop.
Redefining How Data, Optics, and Computation Converge
CubeVi breaks the bottleneck — merging the bridge, timing logic, and optical field into a single real-time light computation framework that delivers both extreme bandwidth and spatial coherence.
Unified Direct-Drive BridgeTCON
CubeVi integrates the display bridge and timing controller (TCON) into a unified direct-drive ASIC that transforms the panel into a photonic-aware computing surface.
Unified Direct-Drive BridgeTCON
CubeVi integrates the display bridge and timing controller (TCON) into a unified direct-drive ASIC that transforms the panel into a photonic-aware computing surface.