Translate quantum advantage into practical utility: quantum-accelerated high-performance computing (HPC) powered by a software-defined quantum processor
Embedded Files
Software-defined quantum processors (SDQs) built from laser-cooled, optically controlled atoms
Hardware co-designed with software and algorithms to directly translate quantum advantage into practical utility
Approaches: From precision atom-photon engineering to real workloads - built as an operable system and validated through KAIST-linked pilots.
Interdisciplinary engineering for atom-photon interactions
Interdisciplinary engineering for atom-photon interactions
Mixed-signal & embedded systems for interfacing neutral-atom processors and human interface
Photonics and optical instrumentation enabling large-scale, high-precision qubit control
Atomic physics & quantum information guiding next-generation control, measurement design, and system-level error budgeting
Quantum Hardware-integrated applications and operations
Quantum Hardware-integrated applications and operations
Quantum simulation & optimization framing problems, benchmarking performance, and integrating hybrid workflows
AI for control engineering delivering data-driven calibration, error mitigation, and control policies for atom-based QIP
Quantum advantage design to connect quantum capabilities with practical compute pipelines.
KAIST-linked R&D and
pilot collaborations
KAIST-linked R&D and
pilot collaborations
Rapid pilot PoCs on neutral-atom systems under development at KAIST OQT Lab in the department of physics at KAIST
Collaborative programs with academia & industry through joint projects and pilot-style engagements
Scholarly engagement via publications, conferences, and community participation
Page updated
Google Sites
Report abuse