Keysight and NPL announce cryogenic RF power measurement breakthrough

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Keysight Technologies has announced what is being described as a groundbreaking achievement in RF power measurement, with the successful demonstration of a commercial RF power sensor operating at cryogenic temperatures as low as 3 kelvin.

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This is a crucial enabler for precise measurements in quantum computing and other cryogenic applications.

Radio Frequency (RF) and microwave power measurements are widely used to support applications across space, defence, and communication and their precise measurement enables engineers to accurately characterise waveforms, components, circuits, and systems.

Taking this a step further, Keysight and the National Physical Laboratory (NPL) have collaborated on a groundbreaking research project, exploring RF power at cryogenic temperatures. This has resulted in the world’s first successful demonstration of a commercial RF power sensor operating at temperatures as low as 3 kelvin (K).

This announcement not only marks a significant technological milestone, but it’s a critical step forward in supporting quantum development and other applications that require cryogenic conditions.

Quantum technology has the potential to achieve major breakthroughs, however, quantum devices such as qubits require operation at cryogenic temperatures and these conditions, while necessary, introduce complexities in maintaining signal integrity and producing precise measurements.

“Our joint efforts have paved the way for advancements in quantum computing and other applications requiring precise RF power measurements at cryogenic temperatures,” said Greg Patschke, General Manager of Keysight’s Aerospace, Defence and Government Solutions Group. “This marks a major milestone, and we are thrilled to have collaborated with the NPL on this groundbreaking research.”

The research focused on utilising Keysight’s N8481S RF power sensor, originally designed for room temperature operation, to perform precise measurements at cryogenic temperatures. The sensor’s thermopile response was meticulously characterised across a range of RF power levels from -35 dBm to 0 dBm in a frequency range from 100 kHz to 10 GHz, ensuring SI traceability through known DC power substitution.

“NPL has over 60 years’ expertise in traceable RF and microwave power metrology research,” said Dr. Murat Celep, Senior Scientist and Science Area Leader at NPL. “This experience, combined with state-of-the-art cryogenic test facilities at NPL and in collaboration with Keysight, has enabled us to demonstrate SI traceable cryogenic power measurements. This is an exciting moment, and we look forward to seeing quantum innovation continue.”

The UK government’s Department for Science, Innovation and Technology (DSIT) supported the research through the UK National Quantum Technologies Programme.