Superconducting.
Qblox offers fully integrated quantum control stacks for superconducting qubits.
Qblox offers fully integrated quantum control stacks for superconducting qubits. These stacks include all necessary instrumentation and software for controlling and reading out superconducting qubits, with signal generation and acquisition capabilities up to 18.5 GHz.
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Our modular approach enables researchers to configure the modules and re-configure the existing modules according to their needs. This approach also makes the system extremely scalable, making our solution ideal for both university research labs and industry R&D labs aiming to scale up their quantum systems.
Faster results
Advanced sequence processors allow real-time pulse parameterization, reducing software-controlled loop overhead, and onboard data processing significantly accelerate experiments.
Excellent analog performance
The Cluster features an analog front-end for low noise pulses with great phase stability maintained over the whole Cluster mainframe.
Open-source software stack
High- and low-level software control, including open-source stack Quantify for controlling and reading out superconducting qubits.
Qblox Superconducting Quantum Control Stacks
Qblox Quantum control stacks are the ideal combination of FPGA-based real-time pulse generation, excellent analog performance, and all-inclusive software layers to enable research labs and industry to scale up to hundreds of qubits seamlessly, allowing quantum error correction and push gate fidelities further. Proprietary SYNQ and LINQ protocols assure fully synchronized channels with low latency feedback for high-fidelity gate operations, active reset, and feedback applications. Low-level access to the Q1 sequence processors further allows advanced control of pulse sequences for more complex measurements.
Parametrized Operations and Speed
Qblox's advanced sequence processors allow real-time pulse parameterization which reduces software-controlled loop overhead, and onboard data processing to significantly accelerate experiments. A typical Chevron type of experiment to sweep multiple experimental parameters can be brought down from hours to minutes by avoiding repeated wave uploading. In addition, fast scalable feedback realized by all-to-all connectivity facilitates active reset operation to reduce measurement times even further.
Highly Versatile Quantum Modules
Qblox's Cluster modules offer versatility by adapting to various superconducting qubit systems for qubit manipulation, direct flux-pulsing with DC couple AWG outputs, and multiplexed readouts in a wide bandwidth. Excellent analog performance is assured by the analog front-end for the low noise pulses with great phase stability maintained over the whole Cluster mainframe. Self-calibration tools make it easier for the researchers to reduce the time spent on calibrating the system, and provide high SFDR for precise control.
Open-Source Software with Quantify
Qblox provides an open-source software stack called Quantify for controlling and reading out superconducting qubits. It simplifies characterization, calibration, and advanced measurements. Quantify is compatible with various qubit types, promoting collaboration within the quantum community and reducing the burden of maintaining custom software frameworks.
