Gate-based quantum computers can accelerate computational tasks beyond classical capabilities. Random circuit sampling is a task that has experimentally demonstrated algorithmic quantum advantage on near-term devices, but its practical utility has been limited. Recently, certified randomness generation based on random circuits was demonstrated on a trapped-ion quantum computer, advancing near-term applications. In this work, we connect single-device certified randomness to classically verifiable position verification, a classical communication primitive that avoids long-distance quantum communication challenges. We present a generic compiler that converts any such certified randomness protocol into a secure classically verifiable position verification scheme, extend it to multi-round protocols, and show its equivalence to a relaxed certified randomness variant. Our near-term instantiation based on random circuit sampling demonstrates classically verifiable position verification as a practical application for near-term devices. This article establishes a connection between single-device certified randomness and classically verifiable position verification. Through this connection, it shows that the latter can be implemented using noisy intermediate-scale quantum devices.
Kaleoglu et al. (Wed,) studied this question.