What question did this study set out to answer?

To propose a quantum protocol for GPS that does not depend on device reliability, enhancing security against cyber threats.

January 22, 2026Open Access

Quantum-secured device-independent global positioning system

Puntos clave

To propose a quantum protocol for GPS that does not depend on device reliability, enhancing security against cyber threats.
Introduced a device-independent quantum GPS protocol using a five-qubit entangled state.
Compared superconducting and trapped-ion platforms for code generation based on fidelity and gate times.
Analyzed photonic distribution over 20,200 km considering quantum signal attenuation.
Achieved 98.4% fidelity with superconducting platforms and 99.8% with trapped-ion platforms.
Demonstrated the necessity of low earth orbit constellations or quantum repeaters for scalability.
Showed resilience against cyberattacks due to quantum rigidity.

Resumen

Abstract We propose a device-independent quantum GPS protocol that employs multipartite Bell nonlocality to self-test a [5, 1, 3] [ 5, 1, 3 ] five-qubit entangled state distributed to four satellites and one ground station, providing robust security against cyberattacks. Leveraging quantum rigidity, the protocol removes reliance on device assumptions, thereby bolstering GPS resilience. In the NISQ era, we compare superconducting (98. 4% fidelity, 216 ns gate time) and trapped-ion (99. 8% fidelity, 483 μs gate time) platforms for five-qubit code generation, and analyze photonic distribution over 20, 200 km with 0. 1 dB/km 0. 1 dB / km attenuation, underscoring the necessity of LEO constellations or quantum repeaters for a scalable quantum GPS protocol.

Leer artículo completoexternamente

Me gusta

Guardar

Ver artículo completo