This means that the SHFSG generates spurious-free, stable signals without requiring its users to spend time on mixer calibration or system maintenance. The SHFSG's super-heterodyne frequency conversion scheme operates over a wider frequency band and with better linearity and fewer spurious signals than standard IQ-mixer-based methods. The frequency range from DC to 8.5 GHz enables a single SHFSG to generate a variety of single- and multi-qubit gates. Combined with the SHFQA Quantum Analyzer for real-time qubit readout, the SHFSG represents the second generation of instruments integrating microwave generation and analysis. Multi-qubit gate operations with minimal latency and high fidelity can be realized thanks to an advanced sequencer, a low-latency signal processing chain and low-phase-noise synthesizers. When synchronized by a PQSC, multiple SHFSGs can be combined within a Zurich Instruments QCCS to enable control of many-qubit systems. Controlled by LabOne, its APIs or the LabOne Q Software, the SHFSG supports quantum computing projects with sizes ranging from a few to several hundred qubits. The SHFSG uses a double superheterodyne technique for frequency up-conversion, which eliminates the need for mixer calibration and saves time on system tune-up. Each SHFSG comes with 4 or 8 analog output channels with 14-bit vertical resolution. The Zurich Instruments SHFSG Signal Generator produces qubit control signals in the frequency range from DC to 8.5 GHz with a spurious-free modulation bandwidth of 1 GHz. Non-Contact Atomic Force Microscopy (NC-AFM) Multi-Frequency Atomic Force Microscopy (MF-AFM) Tunable Diode Laser Absorption Spectroscopy Magnetometry with Ensembles of NV Centers Quantum Computing with Superconducting Qubits
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