瑞士苏黎世仪器公司新推出的 GHFLI 和 SHFLI 锁相放大器是行业领先产品,具备先进的微波信号生成、分析和控制功能。在中国区举办新产品线上发布会上,应用科学家李盟博士和 Paolo Navaretti 博士进行了实机演示,展现全新的微波锁相放大器如何将示波器、频谱分析仪、参数扫描仪在内的全套微波测量工具集于一体。
期待您的参与!
As the trend towards smaller devices and higher frequencies continues, faster reliable measurements become more and more important. The GHFLI and SHFLI Microwave Lock-in Amplifiers combine the measurement speed and high noise rejection of lock-in amplifiers with a full microwave measurement suite making them ideal solutions for scientists and engineers working at these frequencies.
This virtual launch event included a presentation of the instruments, a practical demonstration and live Q&A sessions. Read our blog post for the summary of the event and answers to the questions from the live audience.
In this video, Jan, Tobias and Bruno present the SHFQC Qubit Controller and discuss how this instrument can help speed up system tune-up and complex algorithm execution. The presentation includes practical demonstrations showing how to use the SHFQC to control, read out and perform fast feedback on up to 6 superconducting qubits with a single instrument, as well as a discussion of how the SHFQC can be integrated into larger qubit control systems. The answers to the questions asked during the live event are summarized in this blog post.
In this video, Jan, Mark and Bruno present the SHFSG Signal Generator and discuss how this instrument represents the next step for quantum computing control systems. The presentation includes practical demonstrations showing how to operate the instrument at 8.5 GHz without mixer calibration, how to maximize quantum gate fidelities thanks to high-purity signals, and how to control up to 8 superconducting or spin qubits per instrument. The answers to the questions asked during the live event are summarized in this blog post.
In this video, Paolo, Sadik and Tobias provide a technical overview of the SHFQA Quantum Analyzer and discuss its capabilities. Instrument demonstrations show how to measure a resonator at 8 GHz and perform the parallel readout of 16 qubits, as well as how to take advantage of the SHFQA's feedback capabilities and integrate the SHFQA into a 10-instrument Quantum Computing Control System (QCCS). The answers to the questions asked during the live event are summarized in this blog post.