2015
DOI: 10.1103/physrevapplied.3.024010
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Cryogenic Control Architecture for Large-Scale Quantum Computing

Abstract: Solid-state qubits have recently advanced to the level that enables them, in principle, to be scaledup into fault-tolerant quantum computers. As these physical qubits continue to advance, meeting the challenge of realising a quantum machine will also require the engineering of new classical hardware and control architectures with complexity far beyond the systems used in today's fewqubit experiments. Here, we report a micro-architecture for controlling and reading out qubits during the execution of a quantum a… Show more

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Cited by 219 publications
(135 citation statements)
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“…Taking into account the cooling power of dilution refrigerators around 100mK (the typical operating temperature of GaAs qubits) of approximately 1mW, the approach shown here should allow to operate on the order of hundred qubits, even with today's available commercial CMOS processes. With the use of dedicated cryogenic electronics using supply voltages on the order of 10mV instead of 1V, the power consumption could be reduced by another factor 10.000, (1V/10mV) 2 …”
Section: Discussionmentioning
confidence: 99%
“…Taking into account the cooling power of dilution refrigerators around 100mK (the typical operating temperature of GaAs qubits) of approximately 1mW, the approach shown here should allow to operate on the order of hundred qubits, even with today's available commercial CMOS processes. With the use of dedicated cryogenic electronics using supply voltages on the order of 10mV instead of 1V, the power consumption could be reduced by another factor 10.000, (1V/10mV) 2 …”
Section: Discussionmentioning
confidence: 99%
“…The performance observed at cryogenic temperature of the control electronics suggests that three types of multiplexing can be used based on time-division multiple access (TDMA), frequency-division multiple access, and space-division multiple access to significantly reduce the number of interconnects and reduce power dissipation to the cooling power of the refrigerator. The creation of TDMA multiplexers capable of operating at mK temperatures is required, while TDMA demultiplexers and the reminder of the loops can already operate at 1.6-4.2 K. 105,107 The programming of the digital back-end and of the analog front-end can be done with high-speed serial lines, thus minimizing the number of interconnects connecting room temperature devices to cold circuits. In order to minimize the wiring requirements, a first layer of electronic control can be implemented as close as possible to the qubits in terms of temperature and/or physical distance, either on the same silicon substrate or via three-dimensional integration.…”
Section: Scalable Classical Cmos Control Electronics For Fault-toleramentioning
confidence: 99%
“…As a classical electronic interface operated at room temperature involves problems such as linearity of interconnections with the number of qubits, linearly scaled thermal flux to the quantum system, and power dissipated to control each qubit before being attenuated of several orders of Quantum information density scaling D Rotta et al magnitude (often 60-100 dB), cryogenic multiplexing in CMOS is being developed. [105][106][107] A generic implementation of a faulttolerant loop is shown in Fig. 3a.…”
Section: Scalable Classical Cmos Control Electronics For Fault-toleramentioning
confidence: 99%
“…The measurements are significant, since they prove for the first time that cryogenic SPADs in CMOS operation is possible. It could be very useful for the telecommunication electronics [14] for quantum computer [15] in the future.…”
Section: Introductionmentioning
confidence: 99%