New test certifies quantum measurements that simpler methods cannot mimic

Not all quantum measurements are created equal
Ion-Trap processors are among the most advanced and successful platforms of quantum technologies. Part of it is this setup at the University of Innsbruck. Credit: University of Innsbruck

Proving that one quantum measurement is more powerful than another has long been difficult. Physicists from Heinrich Heine University Düsseldorf, Lund University and the University of Innsbruck have now developed and demonstrated a simple technique to certify that a certain class of measurements has properties that cannot be mimicked by simpler means. Their paper is published in the journal PRX Quantum.

Measurements are central to all quantum technologies. They are said to "collapse" the quantum state they act on, destroying its quantum properties and serving as the bridge to the classical world. Curiously, quantum mechanics allows for measurements that are more general than the ones we can directly associate with classical properties of a system.

These generalized measurements, or POVMs, short for Positive Operator Valued Measures, are not just a mathematical curiosity. They are known to improve performance in tasks like distinguishing between quantum states that would otherwise be indistinguishable, extracting more information from quantum sensors and securing quantum communication.

Yet POVMs are difficult to realize in an actual quantum device, and it is often hard to prove that they truly outperform simpler measurements, making it hard to know whether their added complexity is worthwhile. This new certification method gives researchers a practical tool to answer that question.

Not all quantum measurements are created equal
Left: a POVM is called simulable if it can be implemented by performing with probability pk the projective measurement Pk. Right: if a POVM on a single system is simulable, one can simulate as well a bipartite POVM by performing with probability pk the local projective measurement Pk⊗Pk, which, upon marginalization, yields the measurement statistics of the single-body marginals. Credit: PRX Quantum (2026). DOI: 10.1103/nsjr-vnmg

Certifying POVMs that cannot be simulated

"While some POVMs genuinely offer more than standard measurements, others can be 'simulated' using simpler means, such as collections of standard measurements," explains Raphael Brinster from the University of Düsseldorf. Identifying POVMs that cannot be "simulated" by processing standard measurements is therefore key to understanding the benefits of generalized measurements and unlocking their use in quantum devices. Until now, however, guaranteeing that no such simulation exists has been a major challenge.

The collaboration between Düsseldorf, Lund and Innsbruck has developed and demonstrated an algorithm that provides this certification efficiently using only a small set of measurements. The resulting certificate guarantees that no combination of standard measurements could reproduce the POVM's results. Crucially, the certification is not just a theoretical result: It is robust enough to withstand real experimental imperfections, as the team showed by certifying non-simulable measurements on a quantum computer in Innsbruck.

Made possible by a new paradigm in quantum computing

Realizing POVMs on a quantum computer is difficult in practice, since they can have more outcomes than the two a single qubit can produce. Implementing such measurements and certifying them was only made possible by a novel quantum computing platform developed at the University of Innsbruck, one that moves beyond binary qubits to work with logic of arbitrary dimension.

These so-called "qudits" not only promise more efficient quantum information processing but also unlock techniques unavailable with qubits alone. "These results demonstrate that the use of qudits, even just to aid measurements, can greatly increase the utility of quantum technologies," says Martin Ringbauer, who leads the Innsbruck team.

Publication details

Raphael Brinster et al, Robust Certification of Non-Projective Measurements: Theory and Experiment, PRX Quantum (2026). DOI: 10.1103/nsjr-vnmg

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Lisa Lock

Lisa Lock

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Citation: New test certifies quantum measurements that simpler methods cannot mimic (2026, July 10) retrieved 11 July 2026 from https://phys.org/news/2026-07-certifies-quantum-simpler-methods-mimic.html

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