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Overview of a QPU Networking Program

Eric Ostby
February 03
Overview of a QPU Networking Program

Quantum computing will revolutionize industries—from drug discovery and weather modeling to logistics optimization and AI. To realize that potential, we first have to address the challenges to scaling up quantum systems. One way to address these challenges is by interconnecting quantum processing units (QPUs) to create larger, more powerful systems through entanglement-based quantum networking. These networks enable distributed QPUs to share quantum information, effectively expanding computational capacity and paving the way toward fault-tolerant quantum systems. 

The networked integration of QPUs into data centers and high-performance computing environments is no longer a distant vision for the future; it's unfolding today. This progress reflects a broader industry shift: quantum computing has a recognized potential to increase computational power while minimizing the energy consumption required to perform complex computations, such as the massive energy requirements of further developing artificial intelligence. 

Key Components of a QPU Network

QPU networking efforts will at first focus on homogeneous QPU networks: linking together similar types of quantum processors, such as trapped ion QPUs. As the technology advances, different types of quantum processors will be interconnected, for example trapped ion QPUs might be interconnected to cold atom QPUs. Different quantum processors will specialize in distinct tasks. Integrating these different processors will be essential to realizing the full potential of quantum computing. The components of a quantum network that interconnects QPUs are:

  • Entanglement. Entanglement is at the heart of quantum networking. Unlike classical networking, which connects independent devices, entanglement enables QPUs to operate as a single, larger quantum system. This allows for distributed quantum gates and circuits across multiple processors. Without entanglement, a networked quantum system cannot scale into a fault-tolerant quantum computer.
  • Controller. The controller is a critical component that handles the distribution and synchronization of entanglement across the network. It ensures that all processors remain coherently linked and manage the execution of quantum operations seamlessly.
  • Optical Fiber. Optical fibers are a straightforward part of the network, as long as they operate at low-loss wavelengths. These fibers facilitate the exchange of photons, which carry entanglement between QPUs.
  • Transduction. Transduction involves converting qubit signals to optical photons and vice versa. For heterogeneous networks, efficient transduction is essential to link QPUs operating at different wavelengths. While current transduction efficiencies are low, progress is being made in improving this technology.

2024-11-21 webinar networking QPUs quantum computers-0

 

Overview of a QPU Networking Program

This sample program of how networking QPUs might be accomplished emphasizes key steps and components, starting with heterogeneous qubit platforms, such as trapped ions, and leveraging simulation tools to design and refine networks before physical implementation.

Simulation is a critical first step in planning any quantum network, and it’s also essential in building a quantum computer from interconnected QPUs. Simulation enables researchers to evaluate the performance of individual components and the system as a whole. Key elements to simulate include:

  • Qubits. Assess the performance of qubits on a chip.
  • Transducers. Model how efficiently transducers convert signals between microwave, optical, and telecom domains.
  • Optical fibers. Simulate loss and fidelity in photon transmission through fibers connecting the QPUs.

Simulators are powerful design tools when used to guide the selection, design, and fabrication of components. Simulators can also provide helpful insights into whether a QPU network is feasible, given the specific challenges of a project.

After simulation and design, the next step is to implement and operate the network of QPUs. This stage requires setting up the physical infrastructure, establishing entanglement, and ensuring the system can reliably execute quantum operations and quantum gates. As quantum networks become more sophisticated, orchestration plays a critical role in transforming diverse quantum devices into a cohesive system. This includes managing entanglement distribution, coordinating quantum gates, and ensuring reliable operation. Orchestration provides a scalable network infrastructure, just like the classical Internet. Creating a successful network of QPUs with an entanglement-based quantum network requires a system that is software-defined, reliable, and adaptable to changes in the system, such as loss of entanglement or fluctuations in photon generation rates. 

The next step in QPU networking is ensuring robust and consistent entanglement across multiple nodes. This involves setting up and orchestrating high-quality entanglement across the network, and implementing transducers to convert signals from optical frequencies (used for networking) to other domains, such as microwave frequencies for superconducting qubits. Each QPU could require multiple transducers in order to maintain efficient communication. Achieving this milestone will be critical for executing gates and running initial quantum circuits.

2024-11-21 Aliro Webinar - Eric Ostby - New Era of QPU Networking

Once entanglement is established, the next milestone will be demonstrating basic quantum operations across a networked system. Running basic circuits across multiple QPUs will serve as a proof of concept, akin to a “Hello, World” demonstration for quantum networks.This demonstration is likely about 12 to 18 months away, signaling rapid progress in the field.

2024-11-21 Aliro Webinar - Eric Ostby - New Era of QPU Networking-2

After demonstrating these basic operations, the focus shifts to scaling the network for more complex algorithms and real-world applications. Milestones here would include: 

  • Ensuring gates operate with high fidelity and reliability over time, 
  • Running application-specific algorithms across the network to solve meaningful problems.
  • Showing that multiple QPUs can work together to achieve significant speedups and computational advantages over standalone systems.

2024-11-21 Aliro Webinar - Eric Ostby - New Era of QPU Networking-3

The ultimate goal is to transition from simple demonstrations to fully functional quantum computers, built from networked QPUs. Entanglement-based QPU networks are critical for overcoming scalability challenges in quantum computing. The future of quantum computing is not just about building better processors—it’s about building the networks that interconnect them. 

Any organization seriously exploring building a quantum computer should consider taking these steps:

  1. Start by learning about quantum computing and quantum networking through webinars, white papers, and other educational resources. Engage with quantum technology professionals to build your understanding first.
  2. Build a quantum-focused team with expertise and experience in quantum computing and networking. 
  3. Explore collaborations and look for opportunities to work with leading quantum technology providers, especially in quantum computing and quantum networking.
  4. Plan for the future. Prepare your organization to be ready to take advantage of this technology when it becomes viable for commercial applications.
  5. Be open to exploring different quantum computing platforms. There will be many "winners" that specialize in different applications.

Entanglement-based quantum networks are being built today by a variety of organizations for a variety of use cases – benefiting organizations internally, as well as providing great value to an organization’s customers. Telecommunications companies, national research labs, and systems integrators are just a few examples of the organizations Aliro is helping to leverage the capabilities of quantum networking. For more about how the path to quantum computing is paved by quantum networking, watch our on-demand webinar, QPU Networking for High Performance Computing.



Eric Ostby
February 03