Argonne Researchers Optimize Toffoli with Superstaq
Our optimized Toffoli gate implementation demonstrates an 18% reduction in infidelity compared with the canonical implementation as benchmarked on IBM Jakarta with quantum process tomography.
Software
SupercheQ, Quantum Advantage for Distributed Databases
The emergence of commercial quantum hardware has been accompanied by new approaches to benchmarking quantum computers. In addition to application-centric benchmarking approaches such as Infleqtion’s SupermarQ suite, scientists have developed benchmarks based on sampling from random quantum circuits.
Dynamical Decoupling with Superstaq on Amazon Braket
In order to suppress errors in today’s quantum computers, researchers require low-level access to quantum devices. In this blog post, we have provided a pedagogical tutorial to dynamical decoupling.
Infleqtion Announces Collaboration with Morningstar
Infleqtion, the global quantum ecosystem leader, today announced the integration of SuperstaQ, Infleqtion’s flagship quantum software, into Morningstar Direct, Morningstar’s investment and portfolio analysis platform.
Berkeley Lab AQT + Superstaq for SWAP Networks
Experiment demonstrates how software-optimized circuits execute less error-prone quantum algorithms.
ColdQuanta Acquires Super.tech and Announces the Commercial Availability of Hilbert, the World’s First Cold Atom Quantum Computer
Combination of ColdQuanta Hardware and Super.tech Software to Maximize Value of QuantumComputing Investments BOULDER, Colo., and CHICAGO, May 10, 2022 /PRNewswire/ — ColdQuanta, the global quantum ecosystem leader, today announced its acquisition of Chicago-based Super.tech, a world leader in quantum software application and platform development, and the beta launch of Hilbert, the world’s first gate-based cold atom quantum computer. Super.tech’s full … Read more
Hardware-Conscious Optimization of the Quantum Toffoli Gate
While quantum computing holds great potential in combinatorial optimization, electronic structure calculation, and number theory, the current era of quantum computing is limited by noisy hardware. Many quantum compilation approaches can mitigate the effects of imperfect hardware by optimizing quantum circuits for objectives such as critical path length. Few approaches consider quantum circuits in terms of the set of vendor-calibrated operations (i.e., native gates) available on target hardware. This manuscript expands the analytical and numerical approaches for optimizing quantum circuits at this abstraction level. We present a procedure for combining the strengths of analytical native gate-level optimization with numerical optimization. Although we focus on optimizing Toffoli gates on the IBMQ native gate set, the methods presented are generalizable to any gate and superconducting qubit architecture. Our optimized Toffoli gate implementation demonstrates an 18% reduction in infidelity compared with the canonical implementation as benchmarked on IBM Jakarta with quantum process tomography. Assuming the inclusion of multi-qubit cross-resonance (MCR) gates in the IBMQ native gate set, we produce Toffoli implementations with only six multi-qubit gates, a 25% reduction from the canonical eight multi-qubit implementations for linearly connected qubits.