Driving different qubit modalities to peak performance

From arbitrary characterization at the Hamiltonian level to gate-level optimization and designing noise-robust quantum control operations, Boulder Opal delivers a wide range of capabilities tailored to superconducting functionality. Use industry leading simulation, characterization, and optimization tools to supercharge your hardware development.

Don’t just duplicate what others can do - take advantage of the scaling properties of semiconductor spin qubits to get ahead of the competition. Design controls specifically suited to the unique needs of dense qubit arrays enabled by semiconductor manufacturing.

Trapped-ion qubits are perfect by nature - control determines whether or not they deliver real value! Design novel error-robust gates for ion pairs or large arrays, including parallel gate application. We provide a comprehensive toolkit for Mølmer–Sørensen gate design and analysis so you can get the best out of your hardware.

Atomic qubits are intrinsically perfect and immune to most forms of electrical noise - how well you can control them is everything.  Advances in electronics and laser systems now give you access to manipulate these devices with the precision required to meet their potential. Boulder Opal gives you the proven tools to design the most advanced solutions for neutral atom arrays in both analog and gate-model operation.

Applications based on Nitrogen-vacancy (NV) centers in diamond are at the cutting edge of room temperature and biocompatible implementations. Boulder Opal enables use of controls robust to diverse noise sources in state-of-the-art quantum applications such as these and other diamond based systems.