Quantum Computing Business

Products

We offer a broad range of quantum computing–related hardware products and provide procurement and sales services. From control systems and dilution refrigerators to quantum chips and other key components and equipment, we supply products tailored to each customer’s requirements.

ORCA Computing

ORCA Computing is a UK-based pioneer advancing the practical deployment of photonic quantum computing. Built on its proprietary photonic quantum and quantum memory technologies, the company develops quantum systems designed to integrate with high-performance computing (HPC) and AI infrastructure. With applications spanning materials discovery, manufacturing, combinatorial optimization, and machine learning, ORCA Computing delivers implementation-focused solutions that go beyond research use, helping accelerate the industrial adoption of quantum computing.

Quantum Computer

ORCA PT-2

The PT-2 is a photonics-based quantum system developed by ORCA Computing. Built on the company’s proprietary room-temperature technology, it operates without the need for cryogenic cooling, making it easy to deploy within existing data center environments. Based on ORCA’s distinctive photonic and quantum memory technologies, the PT-2 supports the creation of practical quantum computing use cases as well as the development and validation of algorithms for industrial applications. Already deployed at leading research institutions and data centers worldwide, it offers a scalable and practical quantum solution that advances both industrial adoption and R&D.

  • Photonic

Rigetti

Rigetti Computing is a U.S.-based quantum technology company developing superconducting quantum computers. From the design and fabrication of quantum processors to cloud-accessible development and execution environments, Rigetti provides an integrated platform that combines both hardware and software. The company supports research institutions and enterprises in quantum algorithm development, proof-of-concept testing, and application exploration, helping drive the development of an ecosystem for the practical advancement of quantum computing.

Quantum Computer

Novera

Novera is a 9-qubit superconducting quantum processor based on Rigetti Computing’s Ankaa-class technology. It features tunable couplers that enable high-fidelity two-qubit gates, supporting quantum algorithm development, quantum error correction, and the validation of quantum control techniques. Designed for integration into existing dilution refrigerator systems and built with future upgrades in mind, Novera provides research institutions and companies with a flexible platform for building and operating quantum computing environments. * Ankaa-class technology refers to Rigetti Computing’s suite of quantum processor design and control technologies developed through its work on scalable superconducting quantum computers. It is characterized by an architecture designed for both high-fidelity gate performance and scalability, and Novera is built on this technological foundation.

  • Superconducting

Qolab

Qolab is a U.S.-based quantum startup advancing research and development in superconducting quantum computing technologies. The company is focused on improving the performance and practicality of quantum hardware through advances in device design, control technologies, and system implementation. By bridging academic research and industrial applications, Qolab is driving technology development that supports the commercialization of quantum computers as next-generation computing platforms.

Quantum Computer

Qolab Start

Qolab Start is a superconducting quantum computing platform offered by Qolab. It supports the execution and validation of quantum algorithms, helping research institutions and companies advance quantum computing R&D, proof-of-concept projects, and use-case exploration. The platform is also accessible via the cloud, providing flexible access options to meet a range of operational and application requirements. Through integration with various software tools and development environments, Qolab Start helps streamline quantum application development and supports future industrial adoption.

  • Superconducting

IonQ

IonQ is a U.S.-based leader in trapped-ion quantum computing technology. Known for its precise qubit control and strong scalability, the company provides quantum computing systems that are also accessible via the cloud. In addition to hardware development, IonQ places strong emphasis on software and application development, advancing the practical use of quantum technology across a wide range of fields, including optimization, machine learning, and simulation. Through collaborations with research institutions and industry, IonQ is playing a prominent role in supporting the growth of the quantum ecosystem.

Quantum Computer

IonQ Forte Enterprise

IonQ Forte Enterprise is IonQ’s first rack-mounted quantum computer designed for deployment in data center environments. It features 36 Algorithmic Qubits (AQ 36), placing it among the company’s highest-performing commercial systems. Based on trapped-ion technology, it delivers low gate error rates and long coherence times, enabling the reliable execution of complex quantum algorithms. It is also well suited for integration into hybrid computing environments, supporting enterprise quantum application development and real-world operational deployment. * Algorithmic Qubits is IonQ’s performance metric for describing the practical computational capability of a quantum computer. Rather than referring only to raw qubit count, it reflects the level of performance that can be effectively applied to algorithm execution, taking into account factors such as gate fidelity, circuit executability, and error characteristics.

  • Trapped-Ion
Cloud Services

IonQ Aria

IonQ Aria is a high-performance quantum computer based on trapped-ion technology. It supports 25 Algorithmic Qubits (AQ 25) and offers high gate fidelity and stable operational performance, making it well suited for quantum algorithm validation, applied research, and development aimed at practical use. Available via the cloud, Aria enables companies and research institutions to access quantum computing resources with flexibility. Supporting a wide range of applications, including optimization and simulation, it contributes to accelerating both quantum R&D and real-world adoption.

  • Trapped-Ion

QuantWare

QuantWare is a Europe-based quantum technology company developing processor technology for superconducting quantum computers. Through the design and supply of quantum chips, the company works to improve the scalability and ease of implementation of quantum hardware, providing foundational technologies that support research institutions and companies in building quantum systems. With a focus on fostering an open quantum ecosystem, QuantWare contributes to the broader adoption of quantum computing and the acceleration of its industrial applications.

Quantum Computer

Contralto-A17

Contralto-A17 is a superconducting quantum processor in QuantWare’s A-line series. It is designed for quantum computing research, characterization, and system development, supporting device validation and the construction of experimental environments. The processor can serve as a foundation for qubit control, evaluation system development, and application studies within research institutions and corporate R&D teams, enabling work across a broad range of activities from early-stage quantum hardware development to proof-of-concept demonstration. * A-line is QuantWare’s family of superconducting quantum processors developed primarily for quantum error correction (QEC) research and development. Featuring small- to mid-scale qubit configurations and tunable coupler architectures, the series is well suited for experiments on error correction algorithms such as the surface code, as well as for research toward the realization of logical qubits. It is positioned as a foundational technology platform for future fault-tolerant quantum computing and represents the first stage of QuantWare’s QEC roadmap.

  • Superconducting
Quantum Computing Supporting Hardware

Crescendo

Crescendo is a traveling-wave parametric amplifier (TWPA) for quantum computing applications offered by QuantWare. In quantum processor readout chains, it provides highly sensitive amplification of weak signals, supporting the evaluation, control, and advancement of experimental quantum device environments. As a key enabling component for research, development, and system demonstration, Crescendo contributes to the stable operation of quantum computing environments, improved measurement accuracy, and more efficient system implementation studies.

  • Superconducting
Foundry Services

VIO

VIO is a packaging service for quantum devices offered by QuantWare. It addresses the requirements involved in quantum processor implementation, interconnection, and the construction of evaluation environments, supporting device integration for research and system development. By providing a stable implementation platform for proof-of-concept and validation work, VIO helps advance quantum device performance evaluation, improve experimental efficiency, and support development toward practical applications.

  • Superconducting

Quantum Machines

Quantum Machines is a quantum technology company providing control and orchestration infrastructure for quantum computers. Through its proprietary quantum control platform, the company streamlines high-precision qubit control, measurement, and calibration, supporting users from research and development through to real-system operation. With the flexibility to support a wide range of quantum hardware modalities, Quantum Machines is widely used by research institutions and industry as a foundational technology for accelerating quantum system development and enabling stable operation.

Quantum Computing Supporting Hardware

OPX1000

OPX1000 is a high-density hybrid quantum control platform offered by Quantum Machines. Powered by its proprietary Pulse Processing Unit (PPU), it supports high-speed real-time signal processing, adaptive control, and feedback control, enabling advanced qubit control and quantum error correction research. With a high-density channel architecture and strong scalability, the platform also supports integrated operation across multiple units. Through the QUA programming environment and GPU integration, OPX1000 helps improve the efficiency and sophistication of quantum R&D.

  • Trapped-Ion
  • Neutral Atom
  • Silicon Semiconductor
  • Superconducting
Quantum Computing Supporting Hardware

QDAC-II Compact

QDAC-II Compact is a high-precision DC voltage source designed for quantum devices and cryogenic experiments. With its multi-channel output, it enables flexible bias control for multiple qubits or nanodevices, helping establish stable experimental conditions. It combines low-noise performance with high resolution, making it well suited for the precise parameter setting required in quantum measurements and device characterization. Its compact form factor also makes it easy to integrate into experimental setups, contributing to more efficient research and development.

  • Trapped-Ion
  • Neutral Atom
  • Silicon Semiconductor
  • Superconducting
Quantum Computing Supporting Hardware

QDAC-II

QDAC-II is a multi-channel DC voltage source that enables high-precision voltage control for quantum devices and cryogenic experiments. Its high-resolution, low-noise output provides stable biasing for qubits and nanodevices, helping establish highly reproducible experimental environments. With a large number of output channels, it can flexibly support complex experimental setups and multi-device configurations, contributing to more efficient quantum measurement and device development.

  • Trapped-Ion
  • Neutral Atom
  • Silicon Semiconductor
  • Superconducting
Quantum Computing Supporting Hardware

QSwitch

QSwitch is a switching solution designed to streamline signal routing in quantum experiments and cryogenic measurement environments. It enables flexible connection configurations between multiple measurement setups and devices, helping optimize experimental arrangements and improve measurement efficiency. While maintaining high signal integrity, QSwitch supports the creation of stable experimental environments for quantum device evaluation and R&D. It is also effective in reducing the operational burden associated with increasingly complex quantum systems.

  • Trapped-Ion
  • Neutral Atom
  • Silicon Semiconductor
  • Superconducting
Quantum Computing Supporting Hardware

QBox

QBox is a high-performance control and processing platform designed for quantum computing and advanced measurement applications. It enables precise and efficient operation of quantum devices and signal processing, supporting the automation and acceleration of complex experiments. With its flexible architecture and scalability, QBox can be adapted to a wide range of quantum systems and research applications. It also integrates effectively with development environments, making it a core solution for advancing quantum technology R&D.

  • Trapped-Ion
  • Neutral Atom
  • Silicon Semiconductor
  • Superconducting
Quantum Computing Supporting Hardware

QFilter-II

QFilter-II is a filtering solution designed to suppress unwanted noise and high-frequency components in quantum experiments and advanced measurement environments, thereby improving signal quality. As an enabling component for stable quantum device operation and high-precision measurement, it contributes to the overall reliability of experimental setups. Its design is well suited for cryogenic environments and highly sensitive measurement systems, making it a valuable supporting technology for stable qubit control and device characterization.

  • Superconducting
Quantum Computing Supporting Hardware

QCage

QCage is a shielding solution designed to suppress external noise and electromagnetic interference in quantum experiments and high-frequency measurement environments. It helps provide a stable operating environment for highly sensitive quantum devices and measurement instruments, contributing to improved measurement accuracy and reproducibility. By maintaining signal quality, QCage supports the creation of experimental setups well suited for qubit control and device characterization, making it valuable for enhancing the reliability of quantum R&D and advanced measurement applications.

  • Superconducting
Quantum Computing Supporting Hardware

QBoard-II

QBoard-II is an interface board designed to streamline signal routing and connectivity for quantum experiments and high-precision measurement systems. By organizing complex wiring configurations and enabling stable connections between quantum devices and control equipment, it supports the setup and operation of experimental environments. It is compatible with high-frequency signals and multi-channel configurations, allowing flexible system integration in research and development settings. QBoard-II contributes to improved reliability and greater operational efficiency in quantum systems.

  • Superconducting