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A Polar-Modulation-Based Cryogenic Qubit State Controller in 28nm Bulk CMOS

Yanshu Guo, Yaoyu Li, Wenqiang Huang, Songyao Tan, Qichun Liu, Tiefu Li, Ning Deng, Zhihua Wang, Yuanjin Zheng, Hanjun Jiang

202323 citationsDOI

Abstract

In today's mainstream superconducting quantum computing platforms in a dilution refrigerator, the qubits work at a cryogenic temperature (CT) of a few tens of mK, while the qubit controller hardware works on plates with temperature ranging from a few K to room temperature (RT). The highly-integrated cryo-CMOS qubit controller ASIC that can fully work at 3-4K has been proven to be the most feasible way to scale down the quantum computing system [1–5]. In [1], a pulse modulator is implemented with a limited qubit driving capability, which can only generate fixed length symmetric driving pulse. The controllers in [2], [3] generated the RF driving pulse with a frequency division multiplexing (FDM) mode, with the power dissipation of 192mW/qubit and 46.5mW/qubit, respectively. In [4], a local oscillator (LO) was included to improve the controller integration level, and the chip power consumption was 24.1mW/qubit. An arbitrary waveform generation (AWG) functionality digital design was presented in [5] with a power consumption of 23.1mW/qubit. Nevertheless, with continuously increasing number of qubits to integrate, it remains as one of the major tasks to further reduce the power consumption and size of controller.

Topics & Concepts

QubitQuantum computerElectronic engineeringComputer scienceController (irrigation)CMOSChipMultiplexingPhysicsElectrical engineeringEngineeringQuantumQuantum mechanicsAgronomyBiologyQuantum and electron transport phenomenaQuantum Information and CryptographyQuantum Computing Algorithms and Architecture
A Polar-Modulation-Based Cryogenic Qubit State Controller in 28nm Bulk CMOS | Litcius