Quantum Brilliance Launches Qristal SDK for Room-Temperature Quantum Accelerator Applications

Quantum Brilliance, an Australian company specializing in quantum computing products, has announced the full release of its Qristal SDK. This open-source software development kit allows researchers to develop and test quantum algorithms for real-world applications. The company’s quantum systems use synthetic diamonds to operate at room temperature, making them more accessible and practical for various industries. Potential use cases include data centres, computational chemistry, robotics, autonomous vehicles, and satellites.

Introduction

Quantum Brilliance has released its Qristal SDK, an open-source software development kit for researching applications integrating the company’s portable, diamond-based quantum accelerators. The SDK allows researchers to develop and test quantum algorithms for real-world applications like data centres, computational chemistry, and edge computing applications like robotics and autonomous vehicles. The company’s quantum systems use synthetic diamonds to operate at room temperature, making them more accessible and energy-efficient than traditional quantum computers. CEO and co-founder Mark Luo believes the SDK will help organizations understand how quantum accelerators can enable and enhance productization and commercialization.

Quantum Brilliance Releases Qristal SDK for Quantum Accelerator Development

Quantum Brilliance, a developer of miniaturised, room-temperature quantum computing products and solutions, has announced the full release of the Qristal SDK. This open-source software development kit is designed for research applications integrating the company’s portable, diamond-based quantum accelerators. Previously in beta, the Qristal SDK is now available for anyone to develop and test novel quantum algorithms for real-world applications designed explicitly for quantum accelerators rather than quantum mainframes.

Potential use cases for the Qristal SDK include classical-quantum hybrid applications in data centres, massively parallelised clusters of accelerators for computational chemistry, and embedded accelerators for edge computing applications such as robotics, autonomous vehicles, and satellites. Mark Luo, CEO and co-founder of Quantum Brilliance believes that the Qristal SDK will help organizations worldwide understand how quantum accelerators can enable and enhance productisation and commercialisation.

Qristal SDK Features and Capabilities

The Qristal SDK offers fully integrated C++ and Python APIs, NVIDIA CUDA features, and customizable noise models to support the development of quantum-enhanced designs. The software also incorporates MPI, the global standard for large-scale parallel computing, allowing users to optimise, simulate, and deploy hybrid applications of parallelised, room-temperature quantum accelerators in high-performance computing (HPC) deployments from supercomputers to edge devices.

Quantum Brilliance’s quantum systems use synthetic diamonds to operate at room temperature in any environment. Unlike large mainframe quantum computers, their small-form devices do not require cryogenics, vacuum systems, or precision laser arrays, consuming significantly less power and enabling deployment onsite or at the edge.

Miniaturisation and Future Applications

Currently, the size of a desktop PC, Quantum Brilliance is working to further miniaturise its technology to the size of a semiconductor chip that can be used on any device, wherever classical computers exist today. This would unlock practical quantum computing for everyone. The Qristal SDK source code, which includes extensive application libraries for VQE, QAOA, quantum machine learning, natural language processing, and more, can be downloaded from the company’s website.

About Quantum Brilliance

Founded in 2019, Quantum Brilliance is a venture-backed quantum products and solutions company developing diamond quantum computers supported by software and applications. Their goal is to enable the mass deployment of quantum technology to propel industries to harness edge computing applications and next-generation supercomputers. Quantum Brilliance has global partnerships in the Americas, EMEA, and Asia Pacific, working with governments, supercomputing centres, research organisations, and industry.

Executive Summary

Quantum Brilliance has released its Qristal SDK, an open-source software development kit for creating applications that integrate with the company’s portable, diamond-based quantum accelerators. The technology, which operates at room temperature, has potential use cases in data centres, computational chemistry, and edge computing applications such as robotics and autonomous vehicles.

• Quantum Brilliance has released the Qristal SDK, an open-source software development kit for researching applications that integrate the company’s portable, diamond-based quantum accelerators.
• The Qristal SDK, now out of beta, allows researchers to develop and test quantum algorithms for real-world applications specifically designed for quantum accelerators rather than quantum mainframes.
• Potential use cases include classical-quantum hybrid applications in data centers, parallelized clusters of accelerators for computational chemistry, and embedded accelerators for edge computing applications such as robotics, autonomous vehicles, and satellites.
• The SDK features fully integrated C++ and Python APIs, NVIDIA CUDA features, customizable noise models, and MPI for large-scale parallel computing.
• Quantum Brilliance’s quantum systems use synthetic diamonds to operate at room temperature without the need for cryogenics, vacuum systems, or precision laser arrays, making them more energy-efficient and portable.
• The company aims to further miniaturize its technology to the size of a semiconductor chip for use in any device, unlocking practical quantum computing for everyone.
• Quantum Brilliance was founded in 2019 and has global partnerships with governments, supercomputing centres, research organizations, and industry.

Read the Report.