Approach

The OpenSuperQPlus project aims to build a quantum computer that, in certain tasks, by far outperforms today’s classical supercomputers by moving from

…Classical Parallel Computing…

…to Quantum Computing…

Candidate applications: quantum simulation in chemistry and materials science, optimisation, network analysis, signal processing and machine learning

Quantum advantages:

parallel computing without parallel hardware
maximum of parallel processes: simultaneously processing the whole input

Quantum challenge:

Probabilistic nature of quantum physics in measurement, readout, sampling
Sensitivity of quantum computing systems to noise

The Stack

The targeted quantum computing system of up to 1,000 qubits consists of a full hard- and software stack.

The Hardware

Processor based on superconducting integrated circuits plus supporting technology: microwave electronics, control infrastructure and cryogenics.

Superconductor

A quantum state showing lossless electrical conduction
Common in metals (e.g. Al, Nb)
Occuring at low temperature

Josephson Junction

Thin barrier between superconductors

The Inner Part

Left panel: A Josephson Junction at the heart of the qubit
Right panel: A cross-shaped qubit with a Josephson Junction at the upper tip
Cross-shape for connectivity

The Outer Part

The chip must be connected to input and output
Control: double chip package
Bridges and pins required

Cryogenics

Helium dilution cryostat
Copper plates to maintain uniform temperature at different stages
Input/output: large wiring load
The shown insert is in an operated steel can

Control Electronics

Qubit control and readout
Scalable to large channel number
Low latency and high synchronisation accuracy
Specialised signal processing

Software

The software stack will be integrated from user access all the way to low-level control and run in a central facility

Programming interface for users
Operable in a high-performance computing environment
Tight integration with classical computers