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Quantum compass tested for Royal Navy ship navigation in lieu of GPS

The quantum sensor was tested within a shipping container on the XV Patrick Blackett. [Credit: Thomas Angus, Imperial College London]

 

 

A prototype quantum sensor with potential applications in GPS-free navigation, developed at Imperial College London in the UK, has been tested in collaboration with the Royal Navy.

The test marks an important step in bringing new quantum technologies out of the lab and into real-world settings.

Many navigation systems today rely on global navigation satellite systems (GNSS), such as GPS, which uses signals from satellites orbiting the Earth. However, GPS navigation is not always accessible. Obstacles like tall buildings can easily block the satellite signals, and the signals are also susceptible to jamming, imitation, or denial, thereby preventing accurate navigation. It has been estimated that a single day of satellite service denial would incur a cost of £1 billion to the UK (around $1.25 billion USD).

Self-contained satellite-free navigation systems do exist; however, current technologies drift over time, meaning they lose accuracy unless regularly calibrated with satellites. The quantum sensor has the potential to remove this drift, significantly improving the accuracy over long timescales.

The Imperial College London team unveiled their first "quantum compass" prototype in 2018, and have since been refining the technology to the point where it can now be tested in the field.

Real-world environments
The latest Imperial quantum sensor was integrated into a Qinetiq NavyPOD -- an interchangeable rapid prototyping platform, before setting sail to London aboard a new Royal Navy research ship, the XV Patrick Blackett.

The experiment is the first step toward understanding the application and exploitation of quantum-enabled navigation, which could provide significant navigational advantages when operating in satellite-denied areas.

Dr. Joseph Cotter, lead scientist on the quantum sensor from the Department of Physics at Imperial, said, "Access to the Patrick Blackett provides us with a unique opportunity to take quantum sensors out of the lab and into the real-world environments, where they are needed."

Commander Michael Hutchinson, Commanding Officer of XV Patrick Blackett, said, "Working with Imperial College London on this project has been an exciting and interesting opportunity for all of us. So far, the testing has gone well, but the technology is still in its very early stages. It's great to be a part of Royal Navy history."

Exploiting ultracold atoms
The Imperial quantum sensor is a new type of accelerometer. Accelerometers measure how an object's velocity changes over time. By combining this information with rotation measurements and the initial position of the object, the current location can be calculated.

Conventional accelerometers are used in many different devices such as mobile phones and laptops. However, these sensors cannot maintain their accuracy over longer periods of time without an external reference.

An earlier prototype of the "quantum compass" technology in the lab at Imperial College London. [Credit: Thomas Angus, Imperial College London]

 

 

The quantum accelerometer uses ultracold atoms to make highly accurate measurements. When cooled to extremely low temperatures, the atoms start to display their "quantum" nature, acting like both matter and waves. As the atoms move through the sensor, an "optical ruler" is formed by using a series of laser pulses. This allows the acceleration of the atoms to be precisely measured.

Quantum legacy
These new tests build on a legacy of quantum research at Imperial. Imperial has formed the Center for Quantum Engineering, Science and Technology (QuEST) to translate discoveries in quantum science into transformative quantum technologies.

Professor Peter Haynes, director of QuEST at Imperial, says, "The quantum accelerometer is a pioneering technology at the forefront of quantum innovation. It has the potential to transform navigation by making it more accurate and secure."

Source: Imperial College London

Published June 2023

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