Building a Flexible Control Framework for Quantum Networks

The Science   

Quantum networks will be essential as we scale up quantum computing. However, scientific communities must address many critical science and engineering challenges before we can deploy quantum networks in a practical way. To solve some of these problems, researchers have developed a new control framework for quantum networks. It consists of a centralized quantum network architecture, a scalable and extensible quantum control plane, and real-time quantum control software. For example, the framework includes a two-level scheduler to support network-wide non-time-critical tasks and node-wide time-critical tasks. When a user submits a request, the two-level scheduler translates it into a series of tasks. It then allocates these tasks to various quantum nodes in the network. This enables efficient and coordinated execution of quantum experiments across multiple distributed nodes. This system can also control and coordinate quantum networks across different locations. This accomplishment brings us a step closer to practical deployment of quantum networks.

The Impact

As quantum networks extend to larger scales and get more complicated, they need to be managed by smart software rather than by people. It is becoming increasingly important to develop simple interfaces for users that mask the system’s complexity (a.k.a. quantum network abstractions), scale up network architecture and protocols, and automate software. This new control framework is modular and flexible. As a result, scientists can easily expand or change it to fit their needs. By supporting various real quantum devices and computer models, this framework helps researchers test different ways to build quantum networks. 

Summary

The Quantum Application Network Testbed for Novel Entanglement Technology (QUANT-NET) researchers have made progress toward the automation of quantum network control and management. The team is deploying and evaluating their centralized quantum network architecture, scalable and extensible quantum control plane, and real-time quantum control software in the QUANT-NET testbed. This research has enabled several basic quantum network operations to be automated in the testbed. These operations include automated quantum node calibration, automated quantum link calibration, on-demand Bell State measurement, and on-demand single photon generation. This research marks a milestone on the road towards the practical deployment of quantum networks and the realization of a quantum internet.

Contact

Inder Monga
Quantum Application Network Testbed for Novel Entanglement Technology (QUANT-NET)
Lawrence Berkeley National Laboratory
inder@es.net

Funding

This work was funded by the Office of Science Advanced Scientific Computing Research program’s Quantum Internet to Accelerate Scientific Discovery. The team included researchers from the Department of Energy’s Lawrence Berkeley National Laboratory; University of California, Berkeley; California Institute of Technology (Caltech); and the University of Innsbruck.

Publications

Monga I. et al, “QUANT-NET: A testbed for quantum networking research over deployed fiber.” QuNet '23: Proceedings of the 1st Workshop on Quantum Networks and Distributed Quantum Computing, 31-37 (2023). [DOI: 10.1145/3610251.3610561] [OSTI ID: 2572764]

Schon D. et al, “The QUANT-NET testbed development and preliminary results.” 2024 IEEE International Conference on Quantum Computing and Engineering (QCE), 1799-1808 (2024). [DOI : 10.1109/QCE60285.2024.00209] [OSTI ID: 2572772]

Yin Y. et al, “Experimental test of Bell-state measurement for narrow-band ion-photon interfaces in the QUANT-NET testbed.” Optical Fiber Communication Conference (OFC) 2025, paper M4E.4 (2025). [DOI: 10.1364/OFC.2025.M4E.4] [OSTI ID: 2572775]